Optical image capturing module

ABSTRACT

An optical image capturing module is provided, including a circuit assembly and a lens assembly. The circuit assembly may include a circuit substrate, a plurality of image sensor elements, a plurality of signal transmission elements, and a multi-lens frame. The image sensor elements may be connected to the circuit substrate. The signal transmission elements may be electrically connected between the circuit substrate and the image sensor elements. The multi-lens frame may be manufactured integrally, be covered on the circuit substrate, and surround the image sensor elements and the signal transmission elements. The lens assembly may include a lens base, an auto-focus lens assembly, and a driving assembly. The lens base may be fixed to a multi-lens frame. The auto-focus lens assembly may have at least two lenses with refractive power.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority from Taiwan Patent Application No. 107128634, filed on Aug. 16, 2018, in the Taiwan Intellectual Property Office, the content of which is hereby incorporated by reference in its entirety for all purposes.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to an optical image capturing module, more particularly to an optical image capturing module which provides a plurality of auto-focus lens assemblies, and has a multi-lens frame manufactured integrally.

2. Description of the Related Art

With respect to the assembly of video-recording devices at present, many problems have been identified but not solved yet, especially the video-recording devices with multiple lenses. Due to the use of multiple lenses, there is a dramatic impact on image quality if an optical axis cannot be accurately aimed at a CMOS active pixel sensor for calibration in the process of assembling and manufacturing image quality.

In addition, even though video-recording devices provide an auto-focus function that can be used when the lens is in motion, the assembling and packaging quality of all components would be difficult to manage owing to the complicated composition of the components of the video recording devices.

Moreover, to meet higher photographic requirements, video-recording devices need to have more lenses, four at the least. Therefore, how to include at least four lenses and still have a fine imaging quality is a critical issue that needs to be addressed. Therefore, there is a need for an optical image capturing module to solve the problem as mentioned above.

SUMMARY OF THE INVENTION

In view of the aforementioned problems, the present disclosure provides an optical image capturing module and a manufacturing method thereof so that an optical axis of each auto-focus lens assembly may overlap a central normal line of the sensing surface and light is able to pass through each auto-focus lens assembly in the accommodating hole, pass through the light channel, and be emitted to the sensing surface to ensure image quality.

On the basis of the aforementioned purpose, the present disclosure provides an optical image capturing module including a circuit assembly and a lens assembly. The circuit assembly may include a circuit substrate, a plurality of image sensor elements, a plurality of signal transmission elements, and a multi-lens frame. The circuit substrate may include a plurality of circuit contacts. Each of the image sensor elements may include a first surface and a second surface. The first surface may be connected to the circuit substrate. The second surface may have a sensing surface and a plurality of image contacts. The plurality of signal transmission elements may be electrically connected between the plurality of circuit contacts on the circuit substrate and each of the plurality of image contacts of each of the image sensor elements. A multi-lens frame may be manufactured integrally, be covered on the circuit substrate, and surround the image sensor elements and the signal transmission elements. The positions corresponding to the sensing surface of the plurality of image sensor elements may have a plurality of light channels. The lens assembly may include a plurality of lens bases, a plurality of auto-focus lens assemblies, and a plurality of driving assemblies. The lens bases may be made of an opaque material and have an accommodating hole passing through two ends of the lens bases so that the lens bases become hollow, and the lens bases may be disposed on the multi-lens frame so that the accommodating hole is connected to the light channel. Each of the auto-focus lens assemblies may have at least two lenses with refractive power, be disposed on the lens base, and be positioned in the accommodating hole. The image planes of each of the auto-focus lens assemblies may be disposed on the sensing surface. An optical axis of each of the auto-focus lens assemblies may overlap the central normal line of the sensing surface in such a way that light is able to pass through each of the auto-focus lens assemblies in the accommodating hole and be emitted to the sensing surface. The plurality of driving assemblies may be electrically connected to the circuit substrate and drive the auto-focus lens assembly to move in a direction of the central normal line of the sensing surface. The auto-focus lens assembly further satisfies the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm; 0<PhiA/PhiD≤0.99; and 0.9≤2(ARE,HEP)≤2.0;

Wherein, f is the focal length of the auto-focus lens assembly. HEP is the entrance pupil diameter of the auto-focus lens assembly. HAF is the half maximum angle of view of the auto-focus lens assembly. PhiD is the maximum value of a minimum side length of an outer periphery of the lens base perpendicular to the optical axis of the auto-focus lens assembly. PhiA is the maximum effective diameter of the auto-focus lens assembly nearest to a lens surface of the image plane. ARE is the arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly, and ending at a point with a vertical height which is a distance from the optical axis to half the entrance pupil diameter.

Preferably, the lens base may include a lens barrel and a lens holder. The lens barrel may have an upper hole which passes through two ends of the lens barrel, and the lens holder may have a lower hole which passes through two ends of the lens holder. The lens barrel may be disposed in the lens holder and be positioned in the lower hole in such a way that the upper hole and the lower hole are connected to constitute the accommodating hole. The lens holder may be fixed on the multi-lens frame in such a way that the image sensor element is positioned in the lower hole. The upper hole of the lens barrel may face the sensing surface of the image sensor element. The auto-focus lens assembly may be disposed in the lens barrel and be positioned in the upper hole. The driving assembly may drive the lens barrel opposite to the lens holder moving in a direction of the central normal line of the sensing surface. PhiD is the maximum value of a minimum side length of an outer periphery of the lens holder perpendicular to the optical axis of the auto-focus lens assembly.

Preferably, the optical image capturing module may further include at least one data transmission line electrically connected to the circuit substrate and transmitting a plurality of sensing signals generated from each of the plurality of image sensor elements.

Preferably, the plurality of image sensor elements may sense a plurality of color images.

Preferably, at least one of the image sensor elements may sense a plurality of black-and-white images and at least one of the image sensor elements may sense a plurality of color images.

Preferably, the optical image capturing module may further include a plurality of IR-cut filters, and the IR-cut filter may be disposed in the lens base, be positioned in the accommodating hole, and be located on the image sensor element.

Preferably, the optical image capturing module may further include a plurality of IR-cut filters, and the IR-cut filter may be disposed in the lens barrel or the lens holder and be positioned on the image sensor element.

Preferably, the optical image capturing module in the present invention may further include a plurality of IR-cut filters, and the lens base may include a filter holder. The filter holder may have a filter hole which passes through two ends of the filter holder. The IR-cut filter may be disposed in the filter holder and be positioned in the filter hole, and the filter holder may correspond to positions of the plurality of light channels and be disposed on the multi-lens frame in such a way that the IR-cut filter is positioned on the image sensor element.

Preferably, the lens base may include a lens barrel and a lens holder. The lens barrel may have an upper hole which passes through two ends of the lens barrel, and the lens holder may have a lower hole which passes through two ends of the lens holder. The lens barrel may be disposed in the lens holder and be positioned in the lower hole. The lens holder may be fixed on the filter holder. The lower hole, the upper hole, and the filter hole are connected to constitute the accommodating hole in such a way that the image sensor element is positioned in the filter hole. The upper hole of the lens barrel faces the sensing surface of the image sensor element. In addition, the auto-focus lens assembly may be disposed in the lens barrel and positioned in the upper hole.

Preferably, materials of the multi-lens frame may include any one of metal, conducting material, and alloy, or any combination thereof.

Preferably, materials of the multi-lens frame may include any one of thermoplastic resin, plastic used for industries, insulating material, or any combination thereof.

Preferably, the multi-lens frame may include a plurality of camera lens holders, each of the camera lens holders may have the light channel and a central axis, and a distance between the central axes of adjacent camera lens holders is a value between 2 mm and 200 mm.

Preferably, the driving assembly may include a voice coil motor.

Preferably, the multi-lens frame may have an outer surface, a first inner surface, and a second inner surface. The outer surface may extend from an edge of the circuit substrate, and have a tilted angle α with a central normal line of the sensing surface, and α is in a value between 1° to 30°. The first inner surface is an inner surface of the light channel, the first inner surface has a tilted angle β with a central normal line of the sensing surface, and β is in a value between 1 to 45°. The second inner surface extends from a top surface of the circuit substrate to the light channel, and has a tilted angle γ with a central normal line of the sensing surface, and γ is in a value between 1° to 3°.

Preferably, the plurality of auto-focus lens assemblies include a first lens assembly and a second lens assembly. A field of view (FOV) of the second lens assembly is larger than that of the first lens assembly.

Preferably, the plurality of auto-focus lens assemblies include a first lens assembly and a second lens assembly. The focal length of the first lens assembly is larger than that of the second lens assembly.

Preferably, the optical image capturing module has at least three auto-focus lens assemblies, including a first lens assembly, a second lens assembly, and a third lens assembly. The field of view (FOV) of the second lens assembly is larger than that of the first lens assembly. The field of view (FOV) of the second lens assembly is larger than 46°, and each of the plurality of image sensor elements correspondingly receiving lights from the first lens assembly and the second lens assembly senses a plurality of color images.

Preferably, the optical image capturing module has at least three auto-focus lens assemblies, including a first lens assembly, a second lens assembly, and a third lens assembly. A focal length of the first lens assembly is larger than that of the second lens assembly, and each of the plurality of image sensor elements correspondingly receiving lights from the first lens assembly and the second lens assembly senses a plurality of color images.

Preferably, the optical image capturing module further satisfies the following conditions:

0<(TH1+TH2)/HOI≤0.95; wherein, TH1 is the maximum thickness of the lens holder. TH2 is the minimum thickness of the lens barrel. HOI is the maximum image height perpendicular to the optical axis on the image plane.

Preferably, the optical image capturing module further satisfies the following conditions:

0 mm<TH1+TH2≤1.5 mm; wherein, TH1 is the maximum thickness of the lens holder. TH2 is the minimum thickness of the lens barrel.

Preferably, the optical image capturing module further satisfy the following conditions:

0<(TH1+TH2)/HOI≤0.95; wherein, TH1 is the maximum thickness of the lens holder. TH2 is the minimum thickness of the lens barrel. HOI is the maximum image height perpendicular to the optical axis on the image plane.

Preferably, the optical image capturing module further satisfies the following conditions:

0.9≤ARS/EHD≤2.0; wherein ARS is the arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly and ending at a maximum effective half diameter point of the lens surface. EHD is the maximum effective half diameter of any surfaces of any lenses in the auto-focus lens assembly.

Preferably, the following conditions are satisfied:

PLTA≤100 μm; PSTA≤100 μm; NLTA≤100 μm; and NSTA 100 μm. SLTA≤100 μm; SSTA≤100 μm. Wherein, HOI is defined as the maximum image height perpendicular to the optical axis on the image plane; PLTA is the lateral aberration of the longest operation wavelength of visible light of a positive tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; PSTA is the lateral aberration of the shortest operation wavelength of visible light of a positive tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; NLTA is the lateral aberration of the longest operation wavelength of visible light of a negative tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; NSTA is the lateral aberration of the shortest operation wavelength of visible light of a negative tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; SLTA is the lateral aberration of the longest operation wavelength of visible light of a sagittal ray fan aberration of the optical image capturing module passing through the margin of the entrance pupil and incident at the image plane by 0.7 HOI; SSTA is the lateral aberration of the shortest operation wavelength of visible light of a sagittal ray fan aberration of the optical image capturing module passing through the margin of the entrance pupil and incident at the image plane by 0.7 HOI.

Preferably, the auto-focus lens assembly may include four lenses with refractive power, which are a first lens, a second lens, a third lens, and a fourth lens sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly satisfies the following condition: 0.1≤InTL/HOS≤0.95. Specifically, HOS is the distance from an object side surface of the first lens to the imaging surface on an optical axis. InTL is the distance on the optical axis from an object side surface of the first lens to an image side surface of the fourth lens.

Preferably, the auto-focus lens assembly may include five lenses with refractive power, which are a first lens, a second lens, a third lens, a four lens, and a fifth lens sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly satisfies the following condition: 0.1≤InTL/HOS≤0.95. Specifically, HOS is the distance from an object side surface of the first lens to the imaging surface on an optical axis. InTL is the distance from an object side surface of the first lens to an image side surface of the fifth lens on an optical axis.

Preferably, the auto-focus lens assembly may include six lenses with refractive power, which are a first lens, a second lens, a third lens, a four lens, a fifth lens, and a sixth lens sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly satisfies the following condition: 0.1≤InTL/HOS≤0.95. HOS is the distance on the optical axis from an object side surface of the first lens to the image plane. InTL is the distance on the optical axis from an object side surface of the first lens to an image side surface of the sixth lens.

The auto-focus lens assembly may include seven lenses with refractive power, which are a first lens, a second lens, a third lens, a four lens, a fifth lens, a sixth lens, and a seventh lens sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly satisfies the following condition: 0.1≤InTL/HOS≤0.95. HOS is the distance from an object side surface of the first lens to the imaging surface on an optical axis. InTL is the distance on the optical axis from an object side surface of the first lens to an image side surface of the seventh lens.

Preferably, the optical image capturing module in the present invention may be applied to one of an electronic portable device, an electronic wearable device, an electronic monitoring device, electronic information device, electronic communication device, machine vision device, vehicle electronic device, and combinations thereof.

On the basis of the purpose as mentioned above, the present invention further provides a manufacturing method of an optical image capturing module, including:

disposing a circuit assembly including a circuit substrate, a plurality of image sensor elements, and a plurality of signal transmission elements;

electrically connecting the plurality of signal transmission elements between the plurality of circuit contacts on the circuit substrate and the plurality of image contacts on a second surface of each of the image sensor elements;

forming a multi-lens frame integrally, and forming a plurality of light channels on a sensing surface of the second surface corresponding to each of the image sensor elements;

covering the multi-lens frame on the circuit assembly and surrounding the plurality of image sensor elements and the signal transmission element of the circuit assembly with the multi-lens frame;

disposing a lens assembly, which includes lens bases, a plurality of auto-focus lens assemblies, and a plurality of driving assemblies;

making the plurality of lens bases with opaque material and forming an accommodating hole on each of the lens bases which passes through two ends of the lens base in such a way that the lens base becomes a hollow shape;

disposing the lens bases on the multi-lens frame to connect the accommodating hole with the light channel;

disposing at least two lenses with refractive power in each of the auto-focus lens assemblies and making each of the auto-focus lens assembly satisfy the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm; 0<PhiA/PhiD≤0.99; and 0≤2(ARE,HEP)≤2.0;

In the conditions above, f is the focal length of the auto-focus lens assembly. HEP is the entrance pupil diameter of the auto-focus lens assembly. HAF is the half maximum angle of view of the auto-focus lens assembly. PhiD is the maximum value of a minimum side length of an outer periphery of the lens base perpendicular to an optical axis of the auto-focus lens assembly. PhiA is the maximum effective diameter of the auto-focus lens assembly nearest to a lens surface of an image plane. ARE is the arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly, and ending at a point with a vertical height which is a distance from the optical axis to half the entrance pupil diameter.

disposing each of the auto-focus lens assemblies on the lens bases and positioning each of the auto-focus lens assemblies in the accommodating hole;

adjusting the image planes of each of the auto-focus lens assemblies of the lens assembly to make the image plane of each of the auto-focus lens assemblies of the lens assembly respectively position on the sensing surface of each of the image sensor elements, and to make the optical axis of each of the auto-focus lens assemblies overlap with a central normal line of the sensing surface; and

electrically connecting each of the driving assemblies to the circuit substrate to couple with each of the auto-focus lens assemblies so as to drive each of the auto-focus lens assemblies to move in a direction of the central normal line of the sensing surface.

The terms for the lens parameters in the embodiments in the present invention and the symbols thereof are listed in detail below as references for the following descriptions.

The lens parameters related to length and height:

HOI denotes the maximum imaging height of the optical image capturing module as shown. HOS denotes the height (a distance from an object side surface of the first lens to the imaging surface on an optical axis) of the optical image capturing module. InTL denotes a distance on the optical axis from an object side surface of the first lens to an image side surface of the last lens. InS denotes a distance from the light diaphragm (aperture) to the image plane on the optical axis. IN12 denotes the distance between the first lens and the second lens of the optical image capturing module. TP1 denotes the thickness of the first lens of the optical image capturing module on the optical axis.

The lens parameters related to materials:

NA1 denotes the dispersion coefficient of the first lens of the optical image capturing module; Nd1 denotes the refractive index of the first lens.

The lens parameters related to a field of view:

The field of view is shown as AF. Half of the field of view is shown as AF. The main ray angle is shown as MRA.

The lens parameters related to the exit and incident pupil:

HEP denotes the entrance pupil diameter of the optical image capturing system. The maximum effective half diameter position of any surface of single lens refers to the vertical height between the effective half diameter (EHD) and the optical axis where the incident light of the maximum view angle of the system passes through the farthest edge of the entrance pupil on the EHD of the surface of the lens. For instance, EHD11 denotes the maximum effective half diameter of the object side surface of the first lens. EHD12 denotes the maximum effective half diameter of the image side surface of the first lens. EHD21 denotes the maximum effective half diameter of the object side surface of the second lens. EHD12 denotes the maximum effective half diameter of the image side surface of the second lens. The maximum effective half diameter of any surface of the rest lenses in the optical image capturing module may be deducted on this basis. PhiA denotes the maximum diameter of the image side surface of the lens closest to the image plane in the optical image capturing module, satisfying the equation PhiA=2*EHD. If the surface is aspheric, the ending point of the maximum effective diameter is the ending point which includes the aspheric surface. An ineffective half diameter (IHD) of any surface of a single lens denotes a surface section of an ending point (If the surface is aspheric, the surface has the ending point of the aspheric coefficient.) extending from the direction away from the optical axis to an effective half diameter on the same surface. PhiB denotes the maximum diameter of the image side surface of the lens closest to the image plane in the optical image capturing module, satisfying the equation PhiB=2*(the maximum effective half diameter EHD+the maximum ineffective half diameter IHD)=PhiA+2*(the maximum ineffective half diameter IHD).

PhiA, also called optical exit pupil, denotes the maximum effective diameter of the image side surface of the lens nearest to the image plane (image space) in the optical image capturing module. PhiA3 is used when the optical exit pupil is located on the image side surface of the third lens. PhiA4 is used when the optical exit pupil is located on the image side surface of the fourth lens. PhiA5 is used when the optical exit pupil is located on the image side surface of the fifth lens. PhiA6 is used when the optical exit pupil is located on the image side surface of the sixth lens. The optical exit pupil thereof may be deducted when the optical image capture module has lenses with different refractive powers. PMR denotes the pupil opening ratio of the optical image capturing module, which satisfies the condition PMR=PhiA/HEP.

The parameters related to a lens surface arc length and a surface outline:

The arc length of the maximum effective half diameter of any surface of a single lens denotes the arc length between two points as the maximum effective diameter along an outline of the lens surface, starting from an intersection point of the lens surface and the optical axis in the optical image capturing module, and ending at point of the maximum effective half diameter, shown as ARS. For instance, ARS11 denotes the arc length of the maximum effective half diameter of the object side surface of the first lens. ARS12 denotes the arc length of the maximum effective half diameter of the image side surface of the first lens. ARS21 denotes the arc length of the maximum effective half diameter of the object side surface of the second lens. ARS22 denotes the arc length of the maximum effective half diameter of the image side surface of the second lens. The arc length of the maximum effective half diameter of any surface of the rest lenses in the optical image capturing module may be deducted on this basis.

The arc length of half the entrance pupil diameter (HEP) of any surface of a single lens denotes the arc length of two points as half the entrance pupil diameter (HEP) along an outline of the lens surface, starting from an intersection point of the lens surface and the optical axis of in the optical image capturing module, and ending at a point with a vertical height which is a distance from the optical axis to half the entrance pupil diameter, shown as ARE. For instance, ARE11 denotes the arc length of half the entrance pupil diameter (HEP) of the object side surface of the first lens. ARE12 denotes the are length of half the entrance pupil diameter (HEP) of the image side surface of the first lens. ARE21 denotes the arc length of half the entrance pupil diameter (HEP) of the object side surface of the second lens. ARE22 denotes the arc length of half the entrance pupil diameter (HEP) of the image side surface of the second lens. The arc length of half the entrance pupil diameter (HEP) of any surface of the rest lenses in the optical image capturing module may be deducted on this basis.

The parameters related to the lens depth:

InRS61 is the horizontal distance parallel to an optical axis from a maximum effective half diameter position to an axial point on the object side surface of the sixth lens (a depth of the maximum effective half diameter). InRS62 is the horizontal distance parallel to an optical axis from a maximum effective half diameter position to an axial point on the image side surface of the sixth lens (the depth of the maximum effective half diameter). The depths of the maximum effective half diameters (sinkage values) of the object side surfaces or the image side surfaces of the other lenses are shown in the same manner as described above.

The parameters related to the lens type:

Critical point C denotes the section point perpendicular to the optical axis in addition to the intersection point with the optical axis on a particular lens surface. For instance, HVT51 is the distance perpendicular to the optical axis between a critical point C51 on an object side surface of the fifth lens and the optical axis. HVT52 is the distance perpendicular to the optical axis between a critical point C52 on an image side surface of the fifth lens and the optical axis. HVT61 is the distance perpendicular to the optical axis between a critical point C61 on an object side surface of the sixth lens and the optical axis. HVT62 is the distance perpendicular to the optical axis between a critical point C62 on an image side surface of the sixth lens and the optical axis. The critical points on the object side surfaces or the image side surfaces of other lenses and the vertical distance from the points to the optical axis are shown in the same manner as described above.

IF711 denotes the inflection point closest to the optical axis on the object side surface of the seventh lens. The sinkage value of the point is SGI711. SGI711 also denotes the horizontal displacement distance from the intersection point of the object side surface of the seventh lens on the optical axis to the inflection point of the object side surface of the seventh lens closest to the optical axis, which is parallel to the optical axis. HIF711 is the vertical distance from the point IF711 to the optical axis. IF721 denotes the inflection point closest to the optical axis on the image side surface of the seventh lens. The sinkage value of the point is SGI721. SGI721 also denotes the horizontal displacement distance from the intersection point of the image side surface of the seventh lens on the optical axis to the inflection point of the image side surface of the seventh lens closest to the optical axis, which is parallel to the optical axis. HIF721 is the vertical distance from the point IF721 to the optical axis.

IF712 denotes the inflection point second closest to the optical axis on the object side surface of the seventh lens. The sinkage value of the point is SGI712. SGI712 also denotes the horizontal displacement distance from the intersection point of the object side surface of the seventh lens on the optical axis to the inflection point of the object side surface of the seventh lens second closest to the optical axis, which is parallel to the optical axis. HIF712 is the vertical distance from the point IF712 to the optical axis. IF722 denotes the inflection point second closest to the optical axis on the image side surface of the seventh lens. The sinkage value of the point is SGI722. SGI722 also denotes the horizontal displacement distance from the intersection point of the image side surface of the seventh lens on the optical axis to the inflection point of the image side surface of the seventh lens second closest to the optical axis, which is parallel to the optical axis. HIF722 is the vertical distance from the point IF722 to the optical axis.

IF713 denotes the inflection point third closest to the optical axis on the object side surface of the seventh lens. The sinkage value of the point is SGI713. SGI713 also denotes the horizontal displacement distance from the intersection point of the object side surface of the seventh lens on the optical axis to the inflection point of the object side surface of the seventh lens third closest to the optical axis, which is parallel to the optical axis. HIF713 is the vertical distance from the point IF713 to the optical axis. IF723 denotes the inflection point third closest to the optical axis on the image side surface of the seventh lens. The sinkage value of the point is SGI723. SGI723 also denotes the horizontal displacement distance from the intersection point of the image side surface of the seventh lens on the optical axis to the inflection point of the image side surface of the seventh lens third closest to the optical axis, which is parallel to the optical axis. HIF723 is the vertical distance from the point IF723 to the optical axis.

IF714 denotes the inflection point fourth closest to the optical axis on the object side surface of the seventh lens. The sinkage value of the point is SGI714. SGI714 also denotes the horizontal displacement distance from the intersection point of the object side surface of the seventh lens on the optical axis to the inflection point of the object side surface of the seventh lens fourth closest to the optical axis, which is parallel to the optical axis. HIF714 is the vertical distance from the point IF714 to the optical axis. IF724 denotes the inflection point fourth closest to the optical axis on the image side surface of the seventh lens. The sinkage value of the point is SGI724. SGI724 also denotes the horizontal displacement distance from the intersection point of the image side surface of the seventh lens on the optical axis to the inflection point of the image side surface of the seventh lens fourth closest to the optical axis, which is parallel to the optical axis. HIF724 is the vertical distance from the point IF724 to the optical axis.

The inflection points on the object side surfaces or the image side surfaces of other lenses and the vertical distance from the points to the optical axis or the sinkage value thereof are shown in the same manner as described above.

The lens parameters related to aberrations:

ODT denotes the optical distortion of the optical image capturing module. TDT denotes the TV distortion, which may be further defined by the degree of the aberration displacement between the image of 50% and 100%. DFS denotes the spherical aberration displacement. DFC denotes the comet aberration displacement.

The present invention provides an optical image capturing module. Wherein, an inflection point may be disposed on the object side surface or the image side surface of the six lens, which may effectively adjust the angle at which each field of view is incident on the sixth lens and make correction on the optical distortion and the TV distortion. In addition, the surface of the sixth lens may be equipped with a greater light path regulating ability, thus enhancing the image quality.

The arc length of any surface of a single lens within the maximum effective half diameter affects the surface's ability to correct the aberration and the optical path differences between each of the fields of view. The longer the arc length is, the better the ability to correct the aberration will be. However, difficulties may be found in the manufacturing process. Therefore, it is necessary to control the arc length of any surface of a single lens within the maximum effective half diameter, especially the ratio (ARS/TP) between the arc length (ARS) of the surface within the maximum effective half diameter and the thickness (TP) of the lens to which the surface belongs on the optical axis. For instance, ARS11 denotes the arc length of the maximum effective half diameter of the object side surface of the first lens. TP1 denotes the thickness of the first lens on the optical axis. The ratio between the two is ARS11/TP1. ARS12 denotes the arc length of the maximum effective half diameter of the image side surface of the first lens. The ratio between ARS12 and TP1 is ARS12/TP1. ARS21 denotes the arc length of the maximum effective half diameter of the object side surface of the second lens. TP2 denotes the thickness of the second lens on the optical axis. The ratio between the two is ARS21/TP2. ARS22 denotes the arc length of the maximum effective half diameter of the image side surface of the second lens. The ratio between ARS22 and TP2 is ARS12/TP2. The ratio between the arc length of the maximum effective half diameter of any surface of the rest lenses in the optical image capturing module and the thickness (TP) of the lens to which the surface belongs on the optical axis may be deducted on this basis. In addition, the optical image capturing module further satisfies the following conditions:

PLTA is the lateral aberration of the longest operation wavelength of visible light of a positive tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI PSTA is the lateral aberration of the shortest operation wavelength of visible light of a positive tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI. NLTA is the lateral aberration of the longest operation wavelength of visible light of a negative tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI. NSTA is the lateral aberration of the shortest operation wavelength of visible light of a negative tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI. SLTA is the lateral aberration of the longest operation wavelength of visible light of a sagittal ray fan aberration of the optical image capturing module passing through the margin of the entrance pupil and incident at the image plane by 0.7 HOI; SSTA is the lateral aberration of the shortest operation wavelength of visible light of a sagittal ray fan aberration of the optical image capturing module passing through the margin of the entrance pupil and incident at the image plane by 0.7 HOI. In addition, the optical image capturing module further satisfies the following conditions: PLTA≤100 μm; PSTA≤100 μm; NLTA≤100 μm NSTA≤100 μm; SLTA≤100 μm; SSTA≤100 μm; |TDT|<250%; 0.1≤InTL/HOS≤0.95; and 0.2≤InS/HOS≤1.1.

MTFQ0 denotes the modulation conversion transferring rate of visible light on the imaging surface by the optical axis at a spatial frequency of 110 cycles/mm. MTFQ3 denotes the modulation conversion transferring rate of visible light on the imaging surface by 0.3HOI at a spatial frequency of 110 cycles/mm. MTFQ7 denotes the modulation conversion transferring rate of visible light on the imaging surface by 0.7HOI at a spatial frequency of 110 cycles/mm. In addition, the optical image capturing module further satisfies the following conditions: MTFQ0≥0.2; MTFQ3≥0.01; and MTFQ7≥0.01.

The arc length of any surface of a single lens within the height of half the entrance pupil diameter (HEP) particularly affects the surface's ability to correct the aberration and the optical path differences between each of the fields of view at the shared area. The longer the arc length is, the better the ability to correct the aberration will be. However, difficulties may be found in the manufacturing process. Therefore, it is necessary to control the arc length of any surface of a single lens within the height of half the entrance pupil diameter (HEP), especially the ratio (ARE/TP) between the arc length (ARE) of the surface within the height of the half the entrance pupil diameter (HEP) and the thickness (TP) of the lens to which the surface belongs on the optical axis. For instance, ARE11 denotes the arc length of the height of the half the entrance pupil diameter (HEP) of the object side surface of the first lens. TP1 denotes the thickness of the first lens on the optical axis. The ratio between the two is ARE11/TP1. ARE12 denotes the arc length of the height of the half the entrance pupil diameter (HEP) of the image side surface of the first lens. The ratio between ARE12 and TP1 is ARE12/TP1. ARE21 denotes the arc length of the height of the half the entrance pupil diameter (HEP) of the object side surface of the second lens. TP2 denotes the thickness of the second lens on the optical axis. The ratio between the two is ARE21/TP2. ARE22 denotes the arc length of the height of the half the entrance pupil diameter (HEP) of the image side surface of the second lens. The ratio between ARE22 and TP2 is ARE22/TP2. The ratio between the arc length of the height of the half the entrance pupil diameter (HEP) of any surface of the rest lenses in the optical image capturing module and the thickness (TP) of the lens to which the surface belongs on the optical axis may be deducted on this basis.

On the basis of the purpose as mentioned above, the present invention further provides an optical image capturing module including a circuit assembly, a lens assembly, and a multi-lens outer frame. The circuit assembly may include a circuit substrate, a plurality of image sensor elements, and a plurality of signal transmission elements. The circuit substrate may include a plurality of circuit contacts. Each of the image sensor elements may include a first surface and a second surface. The first surface may be connected to the circuit substrate. The second surface may have a sensing surface and a plurality of image contacts. The plurality of signal transmission elements may be electrically connected between the plurality of circuit contacts on the circuit substrate and each of the plurality of image contacts of each of the image sensor elements. The lens assembly may include a plurality of lens bases, a plurality of auto-focus lens assemblies, and a plurality of driving assemblies. The lens bases may be made of an opaque material and have an accommodating hole passing through two ends of the lens bases so that the lens bases become hollow, and the lens bases may be disposed on the circuit substrate. Each of the auto-focus lens assemblies may have at least two lenses with refractive power, be disposed on the lens base, and be positioned in the accommodating hole. The image planes of each of the auto-focus lens assemblies may be disposed on the sensing surface. An optical axis of each of the auto-focus lens assemblies may overlap the central normal line of the sensing surface in such a way that light is able to pass through each of the auto-focus lens assemblies in the accommodating hole and be emitted to the sensing surface. The plurality of driving assemblies may be electrically connected to the circuit substrate and drive the auto-focus lens assembly to move in a direction of the central normal line of the sensing surface. Each of the lens bases is respectively fixed to the multi-lens outer frame in order to form a whole body.

The auto-focus lens assembly further satisfy the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm; 0<PhiA/PhiD≤0.99; and 0.9≤2(ARE,HEP)≤2.0;

Wherein, f is the focal length of the auto-focus lens assembly. HEP is the entrance pupil diameter of the auto-focus lens assembly. HAF is the half maximum angle of view of the auto-focus lens assembly. PhiD is the maximum value of a minimum side length of an outer periphery of the lens base perpendicular to the optical axis of the auto-focus lens assembly. PhiA is the maximum effective diameter of the auto-focus lens assembly nearest to a lens surface of the image plane. ARE is the arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly, and ending at a point with a vertical height which is a distance from the optical axis to half the entrance pupil diameter.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of the configuration according to the embodiment in the present invention.

FIG. 2 is a schematic diagram of the multi-lens frame according to the embodiment in the present invention.

FIG. 3 is a schematic diagram of the parameter description according to the embodiment in the present invention.

FIG. 4 is a first schematic implementation diagram according to the embodiment in the present invention.

FIG. 5 is a second schematic implementation diagram according to the embodiment in the present invention.

FIG. 6 is a third schematic implementation diagram according to the embodiment in the present invention.

FIG. 7 is a fourth schematic implementation diagram according to the embodiment in the present invention.

FIG. 8 is a fifth schematic implementation diagram according to the embodiment in the present invention.

FIG. 9 is a sixth schematic implementation diagram according to the embodiment in the present invention.

FIG. 10 is a seventh schematic implementation diagram according to the embodiment in the present invention.

FIG. 11 is an eighth schematic implementation diagram according to the embodiment in the present invention.

FIG. 12 is a ninth schematic implementation diagram according to the embodiment in the present invention.

FIG. 13 is a tenth schematic implementation diagram according to the embodiment in the present invention.

FIG. 14 is an eleventh schematic implementation diagram according to the embodiment in the present invention.

FIG. 15 is a twelfth schematic implementation diagram according to the embodiment in the present invention.

FIG. 16 is a thirteenth schematic implementation diagram according to the embodiment in the present invention.

FIG. 17 is a fourteenth schematic implementation diagram according to the embodiment in the present invention.

FIG. 18 is a fifteenth schematic implementation diagram according to the embodiment in the present invention.

FIG. 19 is a sixteenth schematic implementation diagram according to the embodiment in the present invention.

FIG. 20 is a schematic diagram of the first optical embodiment according to the embodiment in the present invention.

FIG. 21 is a curve diagram of the spherical aberration, the astigmatism, and the optical distortion of the first optical embodiment illustrated sequentially from the left to the right according to the embodiment in the present invention.

FIG. 22 is a schematic diagram of the second optical embodiment according to the embodiment in the present invention.

FIG. 23 is a curve diagram of the spherical aberration, the astigmatism, and the optical distortion of the second optical embodiment illustrated sequentially from the left to the right according to the embodiment in the present invention.

FIG. 24 is a schematic diagram of the third optical embodiment according to the embodiment in the present invention.

FIG. 25 is a curve diagram of the spherical aberration, the astigmatism, and the optical distortion of the third optical embodiment illustrated sequentially from the left to the right according to the embodiment in the present invention.

FIG. 26 is a schematic diagram of the fourth optical embodiment according to the embodiment in the present invention.

FIG. 27 is a curve diagram of the spherical aberration, the astigmatism, and the optical distortion of the fourth optical embodiment illustrated sequentially from the left to the right according to the embodiment in the present invention.

FIG. 28 is a schematic diagram of the fifth optical embodiment according to the embodiment in the present invention.

FIG. 29 is a curve diagram of the spherical aberration, the astigmatism, and the optical distortion of the fifth optical embodiment illustrated sequentially from the left to the right according to the embodiment in the present invention.

FIG. 30 is a schematic diagram of the sixth optical embodiment according to the embodiment in the present invention.

FIG. 31 is a curve diagram of the spherical aberration, the astigmatism, and the optical distortion of the sixth optical embodiment illustrated sequentially from the left to the right according to the embodiment in the present invention.

FIG. 32 is a schematic diagram of the optical image capturing module applied to a mobile communication device according to the embodiment in the present invention.

FIG. 33 is a schematic diagram of the optical image capturing module applied to a mobile information device according to the embodiment in the present invention.

FIG. 34 is a schematic diagram of the optical image capturing module applied to a smart watch according to the embodiment in the present invention.

FIG. 35 is a schematic diagram of the optical image capturing module applied to a smart hat according to the embodiment in the present invention.

FIG. 36 is a schematic diagram of the optical image capturing module applied to a safety monitoring device according to the embodiment in the present invention.

FIG. 37 is a schematic diagram of the optical image capturing module applied to a vehicle imaging device according to the embodiment in the present invention.

FIG. 38 is a schematic diagram of the optical image capturing module applied to a unmanned aircraft device according to the embodiment in the present invention.

FIG. 39 is a schematic diagram of the optical image capturing module applied to an extreme sport imaging device according to the embodiment in the present invention.

FIG. 40 is a flow chart according to the embodiment in the present invention.

FIG. 41 is a seventeenth schematic implementation diagram according to the embodiment in the present invention.

FIG. 42 is an eighteenth schematic implementation diagram according to the embodiment in the present invention.

FIG. 43 is a nineteenth schematic implementation diagram according to the embodiment in the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

To facilitate the review of the technique features, contents, advantages, and achievable effects of the present invention, the embodiments together with the attached drawings are described below in detail. However, the drawings are used for the purpose of indicating and supporting the specification, which may not depict the real proportion of elements and precise configuration in the implementation of the present invention. Therefore, the depicted proportion and configuration of the attached drawings should not be interpreted to limit the scope of implementation of the present invention.

The embodiment of the optical image capturing module and the method thereof in the present invention are explained with reference to the related figures. For ease of understanding, the same elements in the following embodiment are explained in accordance with the same symbols.

As shown in FIG. 1 to FIG. 4, FIG. 7, and FIG. 9 to FIG. 12, the optical image capturing module in the present invention may include a circuit assembly 100 and a lens assembly 200. The lens assembly 100 includes a circuit substrate 120, a plurality of image sensor elements 140, a plurality of signal transmission elements 160, and a multi-lens frame 180. The lens assembly 200 may include a plurality of lens bases 220, a plurality of auto-focus lens assemblies 240, and a plurality of driving assemblies.

Specifically, the circuit substrate 120 may include a plurality of circuit contacts 122. Each of the image sensor elements 140 may include a first surface 142 and a second surface 144. LS is a maximum value of a minimum side length of an outer periphery of the image sensor elements 140 perpendicular to the optical axis on the surface. The first surface 142 may be connected to the circuit substrate 120. The second surface 144 may have a sensing surface 1441. The plurality of signal transmission elements 160 may be electrically connected between the plurality of circuit contacts 122 on the circuit substrate 120 and each of the plurality of image contacts 140 of each of the image sensor elements 146. In an embodiment, the signal transmission elements 160 may be made from the material selected from gold wires, flexible circuit boards, spring needles, solder balls, bumps, or the combination thereof.

In addition, the multi-lens frame 180 may be manufactured integrally, in a molding approach for instance, be covered on the circuit substrate 120, and surround the image sensor elements 140 and the signal transmission elements 160. The positions corresponding to the sensing surface 1441 of the plurality of image sensor elements 140 may have a plurality of light channels 182.

The plurality of lens bases 220 may be made of opaque material and have an accommodating hole 2201 passing through two ends of the lens bases 220 so that the lens bases 220 become hollow, and the lens bases 220 may be disposed on the multi-lens frame 180 so that the accommodating hole 2201 is connected to the light channel 182. In addition, in an embodiment, the reflectance of the multi-lens frame 180 is less than 5% in a light wavelength range of 435-660 nm. Therefore, the effect of the stray light caused by reflection or other factors on the image sensor elements 140 may be prevented after light enters the light channel 182.

Furthermore, in an embodiment, materials of the multi-lens frame include any one of metal, conducting material, and alloy, or any combination thereof, thus increasing the heat dissipation efficiency or decreasing static electricity. This allows the image sensor elements 140 and the auto-focus lens assembly 240 to function more efficiently.

Furthermore, in an embodiment, materials of the multi-lens frame 180 include any one of thermoplastic resin, plastic used for industries, or any combination thereof thus having the advantages of easy processing and light weight. This allows the image sensor elements 140 and the auto-focus lens assembly 240 to function more efficiently.

In an embodiment, as shown in FIG. 2, the multi-lens frame 180 may include a plurality of camera lens holders 181 having the light channel 182 and a central axis. The distance between the central axes of adjacent camera lens holders is a value between 2 mm and 200 mm. Therefore, as shown in FIG. 2 and FIG. 15, the distance between the camera lens holders 181 may be adjusted within this range.

In an embodiment, as shown in FIG. 13 and FIG. 14, the multi-lens frame 180 may be manufactured in a molding approach. In this approach, the mold may be divided into a mold-fixed side 503 and a mold-moving side 502. When the mold-moving side 502 is covered on the mold-fixed side 503, the material may be filled in the mold from the injection port 501 to form the multi-lens frame 180.

The formed multi-lens frame 180 may have an outer surface 184, a first inner surface 186, and second inner surface 188. The outer surface 184 extends from an edge of the circuit substrate 120, and has a tilted angle α with a central normal line of the sensing surface 1441. α is a value between 1° to 30°. The first inner surface 186 is an inner surface of the light channel 182. The first inner surface 186 has a tilted angle β with a central normal line of the sensing surface 1441. β is a value between 1° to 45°. The second inner surface 188 extends from the top surface of the circuit substrate 120 to the light channel 182, and has a tilted angle γ with a central normal line of the sensing surface 1441. γ is a value between 1° to 3°. With the positions of the tilted angle α, β, and γ, inferior quality of the multi-lens frame 180 may be prevented when the mold-moving side 502 is detached from the mold-fixed side 503, thus minimizing the chances for the situations like poor release features and molding flash.

In addition, in another embodiment, the multi-lens frame 180 may also be manufactured integrally by 3D printing. The tilted angle α, β, and γ may be formed according to demands. For instance, the tilted angle α, β, and γ may be used to improve structural intensity and minimize stray light, etc.

Each of the auto-focus lens assemblies 240 may have at least two lenses 2401 with refractive power, be disposed on the lens base 220, and be positioned in the accommodating hole 2201. The image planes of each of the auto-focus lens assemblies 240 may be disposed on the sensing surface 1441. An optical axis of each of the auto-focus lens assemblies 240 may overlap the central normal line of the sensing surface 1441 in such a way that light is able to pass through each of the auto-focus lens assemblies 240 in the accommodating hole 2201, pass through the light channel 182, and be emitted to the sensing surface 1441 to ensure image quality. In addition, PhiB denotes the maximum diameter of the image side surface of the lens nearest to the image plane in each of the auto-focus lens assemblies 240. PhiA, also called the optical exit pupil, denotes a maximum effective diameter of the image side surface of the lens nearest to the image plane (image space) in each of the auto-focus lens assemblies 240.

Each of the driving assemblies 260 may be electrically connected to the circuit substrate 120 and drive each of the auto-focus lens assemblies 240 to move in a direction of the central normal line of the sensing surface 1441.

The auto-focus lens assembly 240 further satisfies the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm; 0<PhiA/PhiD≤0.99; and 0≤2(ARE,HEP)≤2.0;

Specifically, f is the focal length of the auto-focus lens assembly 240. HEP is the entrance pupil diameter of the auto-focus lens assembly 240. HAF is the half maximum angle of view of the auto-focus lens assembly 240. PhiD is the maximum value of a minimum side length of an outer periphery of the lens base perpendicular to the optical axis of the auto-focus lens assembly 240. PhiA is the maximum effective diameter of the auto-focus lens assembly 240 nearest to a lens surface of the image plane. ARE is the arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly 240, and ending at a point with a vertical height which is a distance from the optical axis to half the entrance pupil diameter.

In an embodiment, as shown in FIG. 4 and FIG. 7, the lens base 220 may include the lens barrel 222 and lens holder 224. The lens barrel 222 may have an upper hole 2221 which passes through two ends of the lens barrel 222, and the lens holder 224 may have a lower hole 2241 which passes through two ends of the lens holder 224 with a predetermined wall thickness TH1. PhiD denotes the maximum value of a minimum side length of an outer periphery of the lens holder 224 perpendicular to the optical axis on the surface.

The lens barrel 222 may be disposed in the lens holder 224 and be positioned in the lower hole 2241 with a predetermined wall thickness TH2. PhiC is defined as the maximum diameter of the outer periphery perpendicular to the optical axis on the surface. This allows the upper hole 2221 and the lower hole 2241 to be connected to constitute the accommodating hole 2201. The lens holder 224 may be fixed on the multi-lens frame 180 in such a way that the image sensor element 140 is positioned in the lower hole 2241. The upper hole 2221 of the lens barrel 222 faces the sensing surface 1441 of the image sensor element 140. The auto-focus lens assembly 240 are disposed in the lens barrel 222 and is positioned in the upper hole 2221. The driving assembly 260 may drive the lens barrel opposite to the lens holder moving in a direction of the central normal line of the sensing surface. PhiD is the maximum value of a minimum side length of an outer periphery of the lens holder 224 perpendicular to the optical axis of auto-focus lens assembly 240.

In an embodiment, the optical image capturing module 10 may further include at least one data transmission line 400 electrically connected to the circuit substrate 120 and transmits a plurality of sensing signals generated from each of the plurality of 140 image sensor elements.

Furthermore, as shown in FIG. 9 and FIG. 11, a single data transmission line 400 may be used to transmit a plurality of sensing signals generated from each of the plurality of image sensor elements 140 of a dual lens, three lenses, array, or multi-lens optical image capturing module 10.

In another embodiment, as shown in FIG. 10 and FIG. 12, a plurality of single data transmission lines 400 may separately be disposed to transmit a plurality of sensing signals generated from each of the plurality of image sensor elements 140 of a dual lens, three lenses, array, or multi-lens optical image capturing module 10.

In addition, in an embodiment, the plurality of image sensor elements 140 may sense a plurality of color images. Therefore, the optical image capturing module 10 in the present invention has the efficacy of filming colorful images and colorful videos. In another embodiment, at least one of the image sensor elements 140 may sense a plurality of black-and-white images and at least one of the image sensor elements 140 may sense a plurality of color images. Therefore, the optical image capturing module 10 in the present invention may sense a plurality of black-and-white images together with the image sensor elements 140 of the plurality of color images to acquire more image details and sensitivity needed for filming target objects. This allows the generated images or videos to have higher quality.

In an embodiment, as shown in FIG. 3 to FIG. 8 and FIG. 15 to FIG. 19, the optical image capturing module 10 may further include IR-cut filters 300. The IR-cut filter 300 may be disposed in the lens base 220, located in the accommodating hole 2201, and positioned on the image sensor element 140 to filter out infrared ray. This may prevent image quality of the sensing surface 1441 of the image sensor elements 140 from being affected by the infrared ray. In an embodiment, as shown in FIG. 5, the IR-cut filter 300 may be disposed on the lens barrel 222 and the lens holder 224 and be positioned on the image sensor element 140.

In an embodiment, as shown in FIG. 6, the lens base 220 may include a filter holder 226. The filter holder 226 may have a filter hole 2261. The IR-cut filter 300 may be disposed in the filter holder 226 and be positioned in the filter hole 2261, and the filter holder 226 may correspond to positions of the plurality of light channels 182 and be disposed on the multi-lens frame 180 in such a way that the IR-cut filter 300 is positioned on the image sensor element 40 to filter out the infrared ray. This may prevent image quality of the sensing surface 1441 of the image sensor elements 140 from being affected by the infrared ray.

Therefore, under the condition that the lens base 220 includes a filter holder 226, the lens barrel 222 has an upper hole 2221 which passes through two ends of the lens barrel 222, and the lens holder 224 has a lower hole 2241 which passes through two ends of the lens holder 224, the lens barrel 222 may be disposed in the lens holder 224 and be positioned in the lower hole 2241. The lens holder 224 may be fixed on the filter holder 226. The lower hole 2241, the upper hole 2221, and the filter hole 2261 are connected to constitute the accommodating hole 2201 in such a way that the image sensor element 140 is positioned in the filter hole 2261. The upper hole 2221 of the lens barrel 222 may face the sensing surface 1441 of the image sensor element 140. The auto-focus lens assembly 240 may be disposed may be disposed in the lens barrel 222 and positioned in the upper hole 2221 in such a way that the IR-cut filter 300 is positioned on the image sensor elements 140 to filter out the infrared ray entering the auto-focus lens assembly 240. This may prevent image quality of the sensing surface 1441 of the image sensor elements 140 from being affected by the infrared ray.

In an embodiment, the present invention may be duel lenses of the optical image capturing module 10. Therefore, the plurality of auto-focus lens assemblies 240 may include a first lens assembly and a second lens assembly. A field of view (FOV) of the second lens assembly may be larger than that of the first lens assembly 2411, and the field of view (FOV) of the second lens assembly may be larger than 46°. Therefore, the second lens assembly may be a wide-angle lens assembly.

Specifically, the plurality of auto-focus lens assemblies 240 may include a first lens assembly and a second lens assembly, and the focal length of the first lens assembly is larger than that of the second lens assembly. If a traditional photo in the size of 35 mm (The field of view is 46°) is regarded as a basis, the focal length may be 50 mm. When the focal length of the first lens assembly is larger than 50 mm, the first lens assembly may be a long focal lens assembly. In a preferred embodiment, a CMOS sensor (with a field of view of 70°) with the diagonal of 4.6 mm is regarded as a basis, the focal length is approximately 3.28 mm. When the focal length of the first lens assembly is larger than 3.28 mm, the first lens assembly may be a long focal lens assembly.

In an embodiment, the present invention may be a three-lens optical image capturing module 10. Thus, the optical image capturing module 10 may have at least three auto-focus lens assemblies 240 which may include a first lens assembly, a second lens assembly, and a third lens assembly. The plurality of auto-focus assemblies 240 may include the first lens assembly, the second lens assembly, and the third lens assembly. The field of view (FOV) of the second lens assembly may be larger than that of the first lens assembly, and the field of view (FOV) of the second lens assembly may be larger than 46°. Each of plurality of the image sensor elements 140 correspondingly receiving lights from the first lens assembly 2411 and the second lens assembly 2421 senses a plurality of color images. The image sensor elements 140 corresponding to the third lens assembly may sense a plurality of color images or a plurality of black and white images according to requirements.

In an embodiment, the present invention may be a three-lens optical image capturing module 10. Thus, the optical image capturing module 10 may have at least three auto-focus lens assemblies 240 which may include a first lens assembly, a second lens assembly, and a third lens assembly. The plurality of auto-focus assemblies 240 may include the first lens assembly, the second lens assembly, and the third lens assembly. Moreover, the focal length of the first lens assembly is larger than that of the second lens assembly. Each of plurality of the image sensor elements 140 correspondingly receiving lights from the first lens assembly and the second lens assembly senses a plurality of color images. The image sensor elements 140 corresponding to the third lens assembly may sense a plurality of color images or a plurality of black and white images according to requirements.

In an embodiment, the optical image capturing module 10 further satisfies the following conditions:

0<(TH1+TH2)/HOI≤0.95; specifically, TH1 is the maximum thickness of the lens holder 224; TH2 is the minimum thickness 222 of the lens barrel; HOI is the maximum image height perpendicular to the optical axis on the image plane.

In an embodiment, the optical image capturing module 10 further satisfies the following conditions:

0 mm<TH1+TH2≤1.5 mm; specifically, TH1 is the maximum thickness of the lens holder 224; TH2 is the minimum thickness 222 of the lens barrel.

In an embodiment, the optical image capturing module 10 further satisfies the following conditions:

0.9≤ARS/EHD≤2.0. Specifically, ARS is the arc length along an outline of the lens 2401 surface, starting from an intersection point of any lens 2401 surface of any lens 2401 and the optical axis in the auto-focus lens assembly 240, and ending at a maximum effective half diameter point of the lens 2401 surface; EHD is the maximum effective half diameter of any surface of any lens 2401 in the auto-focus lens assembly 240.

In an embodiment, the optical image capturing module 10 further satisfies the following conditions:

PLTA≤100 m; PSTA≤100 μm; NLTA≤100 μm and NSTA≤100 μm; SLTA≤100 μm; SSTA≤100 μm. Specifically, HOI is first defined as the maximum image height perpendicular to the optical axis on the image plane; PLTA is the lateral aberration of the longest operation wavelength of visible light of a positive tangential ray fan aberration of the optical image capturing module 10 passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; PSTA is the lateral aberration of the shortest operation wavelength of visible light of a positive tangential ray fan aberration of the optical image capturing module 10 passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; NLTA is the lateral aberration of the longest operation wavelength of visible light of a negative tangential ray fan aberration of the optical image capturing module 10 passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; NSTA is the lateral aberration of the shortest operation wavelength of visible light of a negative tangential ray fan aberration of the optical image capturing module 10 passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; SLTA is the lateral aberration of the longest operation wavelength of visible light of a sagittal ray fan aberration of the optical image capturing module 10 passing through the margin of the entrance pupil and incident at the image plane by 0.7 HOI SSTA is the lateral aberration of the shortest operation wavelength of visible light of a sagittal ray fan aberration of the optical image capturing module 10 passing through the margin of the entrance pupil and incident at the image plane by 0.7 HOI.

In addition to the structural embodiment as mentioned above, an optical embodiment related to the auto-focus lens assembly 240 is to be described as follows. The optical image capturing module in the present invention may be designed using three operational wavelengths, namely 486.1 nm, 587.5 nm, 656.2 nm. Wherein, 587.5 nm is the main reference wavelength for the technical features. The optical image capturing module in the present invention may be designed using five operational wavelengths, namely 470 nm, 587.5 am, 656.2 nm. Wherein, 587.5 nm is the main reference wavelength for the technical features.

PPR is the ratio of the focal length f of the optical image capturing module 10 to a focal length fp of each of lenses with positive refractive power. NPR is the ratio of the focal length f of the optical image capturing module 10 to the focal length fn of each of lenses with negative refractive power. The sum of the PPR of all the lenses with positive refractive power is ΣPPR. The sum of the NPR of all the lenses with negative refractive power is ΣNPR. Controlling the total refractive power and total length of the optical image capturing module 10 may be achieved when the following conditions are satisfied: 0.5≤ΣPPR/|ΣNPR≤15. Preferably, the following conditions may be satisfied: 1≤ΣPPR/|ΣNPR|3.0.

In addition, HOI is defined as half a diagonal of a sensing field of the image sensor elements 140 (i.e., the imaging height or the maximum imaging height of the optical image capturing module 10). HOS is a distance on the optical axis from an object side surface of the first lens 2411 to the image plane, which satisfies the following conditions: HOS/HOI≤50; and 0.5≤HOS/f≤150. Preferably, the following conditions are satisfied: 1≤HOS/HOI≤40; 1≤HOS/f≤140. Therefore, the optical image capturing module 10 may be maintained in miniaturization so that the module may be equipped on thin and portable electronic products.

In addition, in an embodiment, at least one aperture may be disposed in the optical image capturing module 10 in the present invention to reduce stray light and enhance imaging quality.

Specifically, the disposition of the aperture may be a front aperture or a middle aperture in the optical image capturing module 10 in the present invention. Wherein, the front aperture is the aperture disposed between the shot object and the first lens 2411. The front aperture is the aperture disposed between the first lens 2411 and the image plane. If the aperture is the front aperture, a longer distance may be created between the exit pupil and the image plane in the optical image capturing module 10 so that more optical elements may be accommodated and the efficiency of image sensor elements receiving images may be increased. If the aperture is the middle aperture, the field of view of the system may be expended in such a way that the optical image capturing module has the advantages of a wide-angle lens. InS is defined as the distance from the aforementioned aperture to the image plane, which satisfies the following condition: 0.1≤InS/HOS≤1.1. Therefore, the features of the optical image capturing module 10 maintained in miniaturization and having wide-angle may be attended simultaneously.

In the optical image capturing module 10 in the present invention, InTL is a distance on the optical axis from an object side surface of the first lens 2411 to an image side surface of the sixth lens 2461. FTP is the sum of the thicknesses of all the lenses with refractive power on the optical axis. The following conditions are satisfied: 0.1≤ΣTP/InTL≤0.9. Therefore, the contrast ratio of system imaging and the yield rate of lens manufacturing may be attended simultaneously. Moreover, an appropriate back focal length is provided to accommodate other elements.

R1 is the curvature radius of the object side surface of the first lens 2411. R2 is the curvature radius of the image side surface of the first lens 2411. The following condition is satisfied: 0.001≤|R1/R2|≤25. Therefore, the first lens 2411 is e with appropriate intensity of positive refractive power to prevent the spherical aberration from increasing too fast. Preferably, the following condition is satisfied: 0.01|R1/R2|<12.

R11 is the curvature radius of the object side surface of the sixth lens 2461. R12 is the curvature radius of the image side surface of the sixth lens 2461. This following condition is satisfied: −7<(R11−R12)/(R11+R12)<50. Therefore, it is advantageous to correct the astigmatism generated by the optical image capturing module 10.

IN12 is the distance between the first lens 2411 and the second lens 2421 on the optical axis. The following condition is satisfied: IN12/f≤60. Therefore, it is beneficial to improve the chromatic aberration of the lenses so as to enhance the performance.

IN56 is the distance between the fifth lens 2451 and the sixth lens 2461 on the optical axis. The following condition is satisfied: IN56/f≤3.0. Therefore, it is beneficial to improve the chromatic aberration of the lens assemblies so as to enhance the performance.

TP1 and TP2 are respectively the thicknesses of the first lens 2411 and the second lens 2421 on the optical axis. The following condition is satisfied: 0.1≤(TP1+IN12)/TP2≤10. Therefore, it is beneficial to control the sensitivity produced by the optical image capturing module so as to enhance the performance.

TP5 and TP6 are respectively the thicknesses of the fifth lens 2451 and the sixth lens 2461 on the optical axis. The following condition is satisfied: 0.1≤(TP6+IN56)/TP5≤15. Therefore, it is beneficial to control the sensitivity produced by the optical image capturing module so as to enhance the performance.

TP2, TP3, and TP4 are respectively the thicknesses of the second lens 2421, the third lens 2431, and the fourth lens 2441 on the optical axis. IN23 is the distance between the second lens 2421 and the third lens 2431 on the optical axis. IN45 is the distance between the third lens 2431 and the fourth lens 2441 on the optical axis. InTL is the distance from an object side surface of the first lens 2411 to an image side surface of the sixth lens 2461. The following condition is satisfied: 0.1≤TP4/(IN34+TP4+IN45)<1. Therefore, it is beneficial to slightly correct the aberration generated by the incident light advancing in the process layer upon layer so as to decrease the overall height of the system.

In the optical image capturing module 10, HVT61 is the distance perpendicular to the optical axis between a critical point C61 on an object side surface of the sixth lens 2461 and the optical axis. HVT62 is the distance perpendicular to the optical axis between a critical point C62 on an image side surface of the sixth lens 2461 and the optical axis. SGC61 is a distance parallel to the optical axis from an axial point on the object side surface of the sixth lens to the critical point C61. SGC62 is the distance parallel to the optical axis from an axial point on the image side surface of the sixth lens to the critical point C62. The following conditions may be satisfied: 0 mm≤HVT61≤3 mm; 0 mm<HVT62≤6 mm; 0≤HVT61/HVT62; 0 mm≤|SGC61|≤0.5 mm; 0 mm<|SGC62|≤2 mm; and 0<|SGC62|/(SGC62|+TP6)≤40.9. Therefore, it may be effective to correct the aberration of the off-axis view field.

The optical image capturing module 10 in the present disclosure satisfies the following condition: 0.2≤HVT62/HOI≤0.9. Preferably, the following condition may be satisfied: 0.3≤HVT62/HOI≤0.8. Therefore, it is beneficial to correct the aberration of surrounding view field for the optical image capturing module.

The optical image capturing module 10 in the present disclosure satisfies the following condition: 0≤HVT62/HOS≤0.5. Preferably, the following condition may be satisfied: 0.2≤HVT62/HOS≤0.45. Hereby, it is beneficial to correct the aberration of surrounding view field for the optical image capturing module.

In the optical image capturing module 10 in the present disclosure, SGI611 denotes a distance parallel to an optical axis from an inflection point on the object side surface of the sixth lens 2461 which is nearest to the optical axis to an axial point on the object side surface of the sixth lens 2461. SGI621 denotes a distance parallel to an optical axis from an inflection point on the image side surface of the sixth lens 2461 which is nearest to the optical axis to an axial point on the image side surface of the sixth lens 2461. The following condition are satisfied: 0<SGI611/(SGI611+TP6)≤0.9; 0<SGI621/(SGI621+TP6)≤0.9. Preferably, the following conditions may be satisfied: 0.1≤SGI611/(SGI611+TP6)≤0.6; 0.1≤SGI621/(SGI621+TP6)≤0.6.

SGI612 denotes a distance parallel to the optical axis from the inflection point on the object side surface of the sixth lens 2461 which is the second nearest to the optical axis to an axial point on the object side surface of the sixth lens 2461. SGI622 denotes a distance parallel to an optical axis from an inflection point on the image side surface of the sixth lens 2461 which is the second nearest to the optical axis to an axial point on the image side surface of the sixth lens 2461. The following conditions are satisfied: 0<SGI612/(SGI612+TP6)≤0.9; 0<SGI622/(SGI622+TP6)≤0.9. Preferably, the following conditions may be satisfied: 0.1≤SGI612/(SGI612+TP6)≤0.6; 0.1≤SGI622/(SGI622+TP6)≤0.6.

HIF611 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface of the sixth lens 2461 which is the nearest to the optical axis and the optical axis. HIF621 denotes the distance perpendicular to the optical axis between an axial point on the image side surface of the sixth lens 2461 and an inflection point on the image side surface of the sixth lens 2461 which is the nearest to the optical axis. The following conditions are satisfied: 0.001 mm≤|HIF611|≤5 mm; 0.001 mm≤|HIF621|≤5 mm. Preferably, the following conditions may be satisfied: 0.1 mm≤|HIF611|≤3.5 mm; 1.5 mm≤|HIF62|≤3.5 mm.

HIF612 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface of the sixth lens 2461 which is the second nearest to the optical axis and the optical axis. HIF622 denotes the distance perpendicular to the optical axis between an axial point on the image side surface of the sixth lens 2461 and an inflection point on the image side surface of the sixth lens which is the second nearest to the optical axis. The following conditions are satisfied: 0.001 mm≤|HIF612|≤5 mm; 0.001 mm≤|HIF622|≤5 mm. Preferably, the following conditions may be satisfied: 0.1 mm≤|HIF622|≤3.5 mm; 0.1 mm≤|HIF612|≤3.5 mm.

HIF613 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface of the sixth lens 2461 which is the third nearest to the optical axis and the optical axis. HF623 denotes the distance perpendicular to the optical axis between an axial point on the image side surface of the sixth lens 2461 and an inflection point on the image side surface of the sixth lens 2461 which is the third nearest to the optical axis. The following conditions are satisfied: 0.001 mm≤HIF613|≤5 mm; 0.001 mm≤|HIF623|≤5 mm. Preferably, the following conditions may be satisfied: 0.1 mm≤HIF623|≤3.5 mm, 0.1 mm≤HIF613|≤3.5 mm.

HIF614 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface of the sixth lens 2461 which is the fourth nearest to the optical axis and the optical axis. HIF624 denotes the distance perpendicular to the optical axis between an axial point on the image side surface of the sixth lens 2461 and an inflection point on the image side surface of the sixth lens 2461 which is the fourth nearest to the optical axis. The following conditions are satisfied: 0.001 mm≤|HIF614|≤5 mm; 0.001 mm≤|HIF624|≤5 mm. Preferably, the following relations may be satisfied: 0.1 mm≤|HIF624|≤3.5 mm and 0.1 mm≤|HIF614|≤3.5 mm.

In the optical image capturing module in the present disclosure, (TH1+TH2)/HOI satisfies the following condition: 0<(TH1+TH2)/HOI≤0.95, or 0<(TH1+TH2)/HOI≤0.5 preferably. (TH1+TH2)/HOS satisfies the following condition: 0<(TH1+TH2)/HOS≤0.95, or 0<(TH1+TH2)/HOS≤0.5 preferably. 2*(TH1+TH2)/PhiA satisfies the following condition: 0<2*(TH1+TH2)/PhiA≤0.95, or 0<2*(TH1+TH2)/PhiA≤0.5 preferably.

In an embodiment of the optical image capturing module 10 in the present disclosure, interchangeably arranging the lenses with a high dispersion coefficient and a low dispersion coefficient is beneficial to correcting the chromatic aberration of optical imaging module.

The equation for the aspheric surface as mentioned above is: z=ch2/[1+[1(k+1)c2h2]0.5]+A4h4+A6h6+A8h8+A10h10+A12h12+A4h14+A16h16+A18h18+A20h20+  (1)

Wherein, z is a position value of the position along the optical axis at the height h where the surface apex is regarded as a reference; k is the conic coefficient: c is the reciprocal of curvature radius; and A4, A6, A8, A10, A12, A14, A16, A18, and A20 are high order aspheric coefficients.

In the optical image capturing module provided by the present disclosure, the material of the lens may be made of glass or plastic. Using plastic as the material for producing the lens may effectively reduce the cost of manufacturing. In addition, using glass as the material for producing the lens may control the heat effect and increase the designed space configured by the refractive power of the optical image capturing module. Moreover, the object side surface and the image side surface from the first lens 2411 to the sixth lens 2471 may be aspheric, which may obtain more control variables. Apart from eliminating the aberration, the number of lenses used may be reduced compared with that of traditional lenses used made by glass. Thus, the total height of the optical image capturing module may be reduced effectively.

Furthermore, in the optical image capturing module 10 provided by the present disclosure, when the surface of the lens is a convex surface, the surface of the lens adjacent to the optical axis is convex in principle. When the surface of the lens is a concave surface, the surface of the lens adjacent to the optical axis is concave in principle.

The optical image capturing module 10 in the present disclosure may be applied to a moving auto-focus optical image capturing system depending on requirements. With the features of a fine aberration correction and a high imaging quality, this module may widely be applied to various fields.

In the optical image capturing module in the present application, at least one of the first lens 2411, the second lens 2421, the third lens 2431, the fourth lens 2441, the fifth lens 2451, and sixth lens 2461 may further be designed as a light filtration element with a wavelength of less than 500 nm depending on requirements. The light filtration element may be realized by coating at least one surface of the specific lens with the filter function, or may be realized by the lens itself having the material capable of filtering short wavelength.

The image plane of the optical image capturing module 10 in the present application may be a plane or a curved surface depending requirements. When the image plane is a curved surface such as a spherical surface with a curvature radius, the incident angle necessary for focusing light on the image plane may be reduced. Hence, it not only contributes to shortening the length (TTL) of the optical image capturing module, but also promotes the relative illuminance.

The First Optical Embodiment

As shown in FIG. 18, the auto-focus lens assembly 240 may include six lenses with refractive power, which are a first lens 2411, a second lens 2421, a third lens 2431, a four lens 2441, a fifth lens 2451, and a sixth lens 2461 sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly 240 satisfies the following condition: 0.1≤InTL/HOS≤0.95. Specifically, HOS is the distance from an object side surface of the first lens 2411 to the imaging surface on an optical axis. InTL is the distance on the optical axis from an object side surface of the first lens 2411 to an image side surface of the sixth lens 2461.

Please refer to FIG. 20 and FIG. 21. FIG. 20 is a schematic diagram of the optical image capturing module according to the first optical embodiment of the present invention. FIG. 21 is a curve diagram of spherical aberration, astigmatism, and optical distortion of the optical image capturing module sequentially displayed from left to right according to the first optical embodiment of the present invention. As shown in FIG. 20, the optical image capturing module includes a first lens 2411, an aperture 250, a second lens 2421, a third lens 2431, a four lens 2441, a fifth lens 2451, a sixth lens 2461, an IR-cut filter 300, an image plane 600, and image sensor elements 140 sequentially displayed from an object side surface to an image side surface.

The first lens 2411 has negative refractive power and is made of a plastic material. The object side surface 24112 thereof is a concave surface and the image side surface 24114 thereof is a concave surface, both of which are aspheric. The object side surface 24112 thereof has two inflection points. ARS11 denotes the arc length of the maximum effective half diameter of the object side surface of the first lens. ARS12 denotes the arc length of the maximum effective half diameter of the image side surface of the first lens. ARE11 denotes the arc length of half the entrance pupil diameter (HEP) of the object side surface of the first lens. ARE12 denotes the arc length of half the entrance pupil diameter (HEP) of the image side surface of the first lens. TP1 is the thickness of the first lens on the optical axis.

SGI111 denotes a distance parallel to the optical axis from the inflection point on the object side surface 24112 of the first lens 2411 which is the nearest to the optical axis to an axial point on the object side surface 24112 of the first lens 2411. SGI121 denotes a distance parallel to an optical axis from an inflection point on the image side surface 24114 of the first lens 2411 which is the nearest to the optical axis to an axial point on the image side surface 24114 of the first lens 2411. The following conditions are satisfied: SGI111=−0.0031 mm; |SGI111|/(|SGI111|+TP1)=0.0016.

SGI112 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24112 of the first lens 2411 which is the second nearest to the optical axis to an axial point on the object side surface 24112 of the first lens 2411. SGI122 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24114 of the first lens 2411 which is the second nearest to the optical axis to an axial point on the image side surface 24114 of the first lens 2411. The following conditions are satisfied: SGI112=1.3178 mm; |SGI112|/(|SGI112|+TP1)=0.4052.

HIF111 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24112 of the first lens 2411 which is the nearest to the optical axis and the optical axis. HIF121 denotes the distance perpendicular to the optical axis between an axial point on the image side surface 24114 of the first lens 2411 and an inflection point on the image side surface 24114 of the first lens 2411 which is the nearest to the optical axis. The following conditions are satisfied: HIF111=0.5557 mm; HIF111/HOI=0.1111.

HIF112 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24112 of the first lens 2411 which is the second nearest to the optical axis and the optical axis. HIF122 denotes the distance perpendicular to the optical axis between an axial point on the image side surface 24114 of the first lens 2411 and an inflection point on the image side surface 24114 of the first lens 2411 which is the second nearest to the optical axis. The following conditions are satisfied: HIF112=5.3732 mm; HIF112/HOI=1.0746.

The second lens 2421 has positive refractive power and is made of a plastic material. The object side surface 24212 thereof is a convex surface and the image side surface 24214 thereof is a convex surface, both of which are aspheric. The object side surface 24212 thereof has an inflection point. ARS21 denotes the arc length of the maximum effective half diameter of the object side surface of the second lens. ARS22 denotes the arc length of the maximum effective half diameter of the image side surface of the second lens. ARE21 denotes an arc length of half the entrance pupil diameter (HEP) of the object side surface of the second lens. ARE22 denotes the arc length of half the entrance pupil diameter (HEP) of the image side surface of the second lens. TP2 is the thickness of the second lens on the optical axis.

SGI211 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24212 of the second lens 2421 which is the nearest to the optical axis to an axial point on the object side surface 24212 of the second lens 2421. SGI221 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24214 of the second lens 2421 which is the nearest to the optical axis to an axial point on the image side surface 24214 of the second lens 2421. The following conditions are satisfied: SGI211=0.1069 mm; |SGI211|/(|SGI211|+TP2)=0.0412; SGI221=0 mm; |SGI221|/(|SGI221|+TP2)=0.

HIF211 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24212 of the second lens 2421 which is the nearest to the optical axis and the optical axis. HIF221 denotes the distance perpendicular to the optical axis between an axial point on the image side surface 24214 of the second lens 2421 and an inflection point on the image side surface 24214 of the second lens 2421 which is the nearest to the optical axis. The following conditions are satisfied: HIF211=1.1264 mm; HIF211/HOI=0.2253; HIF221=0 mm; HIF221/HOI=0.

The third lens 2431 has negative refractive power and is made of a plastic material. The object side surface 24312 thereof is a concave surface and the image side surface 24314 thereof is a convex surface, both of which are aspheric. The object side surface 24312 and the image side surface 24314 thereof both have an inflection point. ARS31 denotes the arc length of the maximum effective half diameter of the object side surface of the third lens. ARS32 denotes an arc length of the maximum effective half diameter of the image side surface of the third lens. ARE31 denotes the are length of half the entrance pupil diameter (HEP) of the object side surface of the third lens. ARE32 denotes the arc length of half the entrance pupil diameter (HEP) of the image side surface of the third lens. TP3 is the thickness of the third lens on the optical axis.

SGI311 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24312 of the third lens 2431 which is the nearest to the optical axis to an axial point on the object side surface 24312 of the third lens 2431. SGI321 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24314 of the third lens 2431 which is the nearest to the optical axis to an axial point on the image side surface 24314 of the third lens 2431. The following conditions are satisfied: SGI311=−0.3041 mm; |SGI311|(|SGI311|+TP3)=0.4445; SGI321=−0.1172 mm; |SGI321|/(|SGI321|+TP3)=0.2357.

HIF311 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24312 of the third lens 2431 which is the nearest to the optical axis and the optical axis. HIF321 denotes the distance perpendicular to the optical axis between an axial point on the image side surface 24314 of the third lens 2431 and an inflection point on the image side surface 24314 of the third lens 2431 which is the nearest to the optical axis. The following conditions are satisfied: HIF311=1.5907 mm; HIF311/HOI=0.3181; HIF321=1.3380 mm; HIF321/HOI=0.2676.

The fourth lens 2441 has positive refractive power and is made of a plastic material. The object side surface 24412 thereof is a convex surface and the image side surface 24414 thereof is a concave surface, both of which are aspheric. The object side surface 24412 thereof has two inflection points and the image side surface 24414 thereof has an inflection point. ARS41 denotes the arc length of the maximum effective half diameter of the object side surface of the fourth lens. ARS42 denotes the arc length of the maximum effective half diameter of the image side surface of the fourth lens. ARE41 denotes the arc length of half the entrance pupil diameter (HEP) of the object side surface of the fourth lens. ARE42 denotes the arc length of half the entrance pupil diameter (HEP) of the image side surface of the fourth lens. TP4 is the thickness of the fourth lens on the optical axis.

SGI411 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24412 of the fourth lens 2441 which is the nearest to the optical axis to an axial point on the object side surface 24412 of the fourth lens 2441. SGI421 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24414 of the fourth lens 2441 which is the nearest to the optical axis to an axial point on the image side surface 24414 of the fourth lens 2441. The following conditions are satisfied: SGI411=0.0070 mm; |SGI411|/(|SGI411|+TP4)=0.0056; SGI421=0.0006 mm; |SGI421|/(|SGI421|+TP4)=0.0005.

SGI412 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24412 of the fourth lens 2441 which is the second nearest to the optical axis to an axial point on the object side surface 24412 of the fourth lens 2441. SGI422 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24414 of the fourth lens 2441 which is the second nearest to the optical axis to an axial point on the image side surface 24414 of the fourth lens 2441. The following conditions are satisfied: SGI412=−0.2078 mm; SGI412|/(|SGI412|+TP4)=0.1439.

HIF411 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24412 of the fourth lens 2441 which is the nearest to the optical axis and the optical axis. HIF421 denotes the distance perpendicular to the optical axis between an axial point on the image side surface 24414 of the fourth lens 2441 and an inflection point on the image side surface 24414 of the fourth lens 2441 which is the nearest to the optical axis. The following conditions are satisfied: HIF411=0.4706 mm; HIF411/HOI=0.0941; HIF421=0.1721 mm; HIF421/HOI=0.0344.

HIF412 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24412 of the fourth lens 2441 which is the second nearest to the optical axis and the optical axis. HIF422 denotes the distance perpendicular to the optical axis between an axial point on the image side surface 24414 of the fourth lens 2441 and an inflection point on the image side surface 24414 of the fourth lens 2441 which is the second nearest to the optical axis. The following conditions are satisfied: HIF412=2.0421 mm; HIF412/HOI=0.4084.

The fifth lens 2451 has positive refractive power and is made of a plastic material. The object side surface 24512 thereof is a convex surface and the image side surface 24514 thereof is a convex surface, both of which are aspheric. The object side surface 24512 thereof has two inflection points and the image side surface 24514 thereof has an inflection point. ARS51 denotes the arc length of the maximum effective half diameter of the object side surface of the fifth lens. ARS52 denotes the arc length of the maximum effective half diameter of the image side surface of the fifth lens. ARE51 denotes the arc length of half the entrance pupil diameter (HEP) of the object side surface of the fifth lens. ARE52 denotes the arc length of half the entrance pupil diameter (HEP) of the image side surface of the fifth lens. TP5 is the thickness of the fifth lens on the optical axis.

SGI511 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24512 of the fifth lens 2451 which is the nearest to the optical axis to an axial point on the object side surface 24512 of the fifth lens 2451. SGI521 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24514 of the fifth lens 2451 which is the nearest to the optical axis to an axial point on the image side surface 24514 of the fifth lens 2451. The following conditions are satisfied: SGI511=0.00364 mm; |SGI511|/(|SGI511|+TP5)=0.00338: SGI521=−0.63365 mm; |SGI521|/(|SGI521|+TP5)=0.37154.

SGI512 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24512 of the fifth lens 2451 which is the second nearest to the optical axis to an axial point on the object side surface 24512 of the fifth lens 2451. SGI522 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24514 of the fifth lens 2451 which is the second nearest to the optical axis to an axial point on the image side surface 24514 of the fifth lens 2451. The following conditions are satisfied: SGI512=−0.32032 mm; |SGI512|/(|SGI512|+TP5)=0.23009.

SGI513 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24512 of the fifth lens 2451 which is the third nearest to the optical axis to an axial point on the object side surface 24512 of the fifth lens 2451. SGI523 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24514 of the fifth lens 2451 which is the third nearest to the optical axis to an axial point on the image side surface 24514 of the fifth lens 2451. The following conditions are satisfied: SGI513=0 mm; |SGI513|/(|SGI513|+TP5)=0; SGI523=0 mm; |SGI523|/(|SGI523|+TP5)=0.

SGI514 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24512 of the fifth lens 2451 which is the fourth nearest to the optical axis to an axial point on the object side surface 24512 of the fifth lens 2451. SGI524 denotes a distance parallel to an optical axis from an inflection point on the image side surface 24514 of the fifth lens 2451 which is the fourth nearest to the optical axis to an axial point on the image side surface 24514 of the fifth lens 2451. The following conditions are satisfied: SGI514=0 mm; |SGI514|/(|SGI514|+TP5)=0: SGI524=0 mm; |SGI524|/(|SGI524|+TP5)=0.

HIF511 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24512 of the fifth lens 2451 which is the nearest to the optical axis and the optical axis. HIF521 denotes the distance perpendicular to the optical axis between the optical axis and an inflection point on the image side surface 24514 of the fifth lens 2451 which is the nearest to the optical axis. The following conditions are satisfied: HIF511=0.28212 mm; HIF511/HOI=0.05642; HIF521=2.13850 mm; HIF521/HOI=0.42770.

HIF512 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24512 of the fifth lens 2451 which is the second nearest to the optical axis and the optical axis. HIF522 denotes the distance perpendicular to the optical axis between the optical axis and an inflection point on the image side surface 24514 of the fifth lens 2451 which is the second nearest to the optical axis. The following conditions are satisfied: HIF512=2.51384 mm; HIF512/HOI=0.50277.

HIF513 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24512 of the fifth lens 2451 which is the third nearest to the optical axis and the optical axis. HIF523 denotes the distance perpendicular to the optical axis between the optical axis and an inflection point on the image side surface 24514 of the fifth lens 2451 which is the third nearest to the optical axis. The following conditions are satisfied: HHIF513=0 mm; HIF513/HOI=0; HIF523=0 mm; HIF523/HOI=0.

HIF514 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24512 of the fifth lens 2451 which is the fourth nearest to the optical axis and the optical axis. HIF524 denotes the distance perpendicular to the optical axis between the optical axis and an inflection point on the image side surface 24514 of the fifth lens 2451 which is the fourth nearest to the optical axis. The following conditions are satisfied: HIF514=0 mm; HIF514/HOI=0; HIF524=0 mm; HIF524/HOI=0.

The sixth lens 2461 has negative refractive power and is made of a plastic material. The object side surface 24612 thereof is a concave surface and the image side surface 24614 thereof is a concave surface. The object side surface 24612 has two inflection points and the image side surface 24614 thereof has an inflection point. Therefore, it may be effective to adjust the angle at which each field of view is incident on the sixth lens to improve the aberration. ARS61 denotes the arc length of the maximum effective half diameter of the object side surface of the sixth lens. ARS62 denotes the arc length of the maximum effective half diameter of the image side surface of the sixth lens. ARE61 denotes the arc length of half the entrance pupil diameter (HEP) of the object side surface of the sixth lens. ARE62 denotes the arc length of half the entrance pupil diameter (HEP) of the image side surface of the sixth lens. TP6 is the thickness of the sixth lens on the optical axis.

SGI611 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24612 of the sixth lens 2461 which is the nearest to the optical axis to an axial point on the object side surface 24612 of the sixth lens 2461. SGI621 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24614 of the sixth lens 2461 which is the nearest to the optical axis to an axial point on the image side surface 24614 of the sixth lens 2461. The following conditions are satisfied: SGI611=−0.38558 mm; |SGI611|/(|SGI611|+TP6)=0.27212; SGI621=0.12386 mm; |SGI621|/(|SGI621|+TP6)=0.10722.

SGI612 denotes the distance parallel to the optical axis from the inflection point on the object side surface 24612 of the sixth lens 2461 which is the second nearest to the optical axis to an axial point on the object side surface 24612 of the sixth lens 2461. SGI621 denotes the distance parallel to an optical axis from an inflection point on the image side surface 24614 of the sixth lens 2461 which is the second nearest to the optical axis to an axial point on the image side surface 24614 of the sixth lens 2461. The following conditions are satisfied: SGI612=−0.47400 mm; |SGI612|/(|SGI612|+TP6)=0.31488; SGI622=0 mm; |SGI622|/(|SGI622|+TP6)=0.

HIF611 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24612 of the sixth lens 2461 which is the nearest to the optical axis and the optical axis. HIF621 denotes the distance perpendicular to the optical axis between the inflection point on the image side surface 24614 of the sixth lens 2461 which is the nearest to the optical axis and the optical axis. The following conditions are satisfied: HIF611=2.24283 mm; IF611/HOI=0.44857; HIF621=1.07376 mm; HIF621/HOI=0.21475.

HIF612 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24612 of the sixth lens 2461 which is the second nearest to the optical axis and the optical axis. HIF622 denotes the distance perpendicular to the optical axis between the inflection point on the image side surface 24614 of the sixth lens 2461 which is the second nearest to the optical axis and the optical axis. The following conditions are satisfied: HIF611=2.24283 mm; HIF612=2.48895 mm; HIF612/HOI=0.49779.

HIF613 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24612 of the sixth lens 2461 which is the third nearest to the optical axis and the optical axis. HIF623 denotes the distance perpendicular to the optical axis between the inflection point on the image side surface 24614 of the sixth lens 2461 which is the third nearest to the optical axis and the optical axis. The following conditions are satisfied: HIF613=0 mm; HIF613/HOI=0; HIF623=0 mm; HIF623/HOI=0.

HIF614 denotes the distance perpendicular to the optical axis between the inflection point on the object side surface 24612 of the sixth lens 2461 which is the fourth nearest to the optical axis and the optical axis. HIF624 denotes the distance perpendicular to the optical axis between the inflection point on the image side surface 24614 of the sixth lens 2461 which is the fourth nearest to the optical axis and the optical axis. The following conditions are satisfied: HIF614=0 mm; HIF614/HOI=0; HIF624=0 mm; HIF624/HOI=0.

The IR-cut filter 300 is made of glass and is disposed between the sixth lens 2461 and the image plane 600, which does not affect the focal length of the optical image capturing module.

In the optical image capturing module of the embodiment, f is the focal length of the lens assembly. HEP is the entrance pupil diameter. HAF is half of the maximum view angle. The detailed parameters are shown as below: f=4.075 mm, f/HEP=1.4, HAF=50.001°, and tan(HAF)=1.1918.

In the optical image capturing module of the embodiment, f1 is the focal length of the first lens assembly 2411. f6 is a focal length of the sixth lens assembly 2461.

The following conditions are satisfied: f1=−7.828 mm; |f/f1|=0.52060; f6=−4.886; and |f1|>|f6|.

In the optical image capturing module of the embodiment, the focal lengths of the second lens 2421 to the fifth lens 2451 are f2, f3, f4, and f5, respectively. The following conditions are satisfied: |f2|+|f3|+|f4|+|f5|=95.50815 mm; |f1|+|f6|=12.71352 mm and |f2|+|f3|+|f4|+|f5|>f1|+f6|.

PPR is the ratio of the focal length f of the optical image capturing module to a focal length fp of each of lenses with positive refractive power. NPR is the ratio of the focal length f of the optical image capturing module to a focal length fn of each of lenses with negative refractive power. In the optical image capturing module of the embodiment, The sum of the PPR of all lenses with positive refractive power is ΣPPR=f/f2+f/f4+f/f5=1.63290. The sum of the NPR of all lenses with negative refractive power is ΣNPR=|f/f1|+|f/3|+|f/f6|=1.51305, and ΣPPR/|ΣNPR|=1.07921. The following conditions are also satisfied: |f/f2|=0.69101; |f/f3|=4.15834; |f/f4|=0.06883; |f/f5|=0.87305: |f/f6|=0.83412.

In the optical image capturing module of the embodiment, InTL is the distance on the optical axis from an object side surface 24112 of the first lens 2411 to an image side surface 24614 of the sixth lens 2461. HOS is the distance on the optical axis from an object side surface 24112 of the first lens 2411 to the image plane 600. InS is a distance from the aperture 250 to the image plane 180. HOI is defined as half the diagonal of the sensing field of the image sensor elements 140. BFL is the distance from the image side surface 24614 of the sixth lens and the image plane 600. The following conditions are satisfied: InTL+BFL=HOS; HOS=19.54120 mm; HOI=5.0 mm; HOS/HOI=3.90824; HOS/f=4.7952; InS=11.685 mm; and InS/HOS=0.59794.

In the optical image capturing module of the embodiment, ΣTP is the sum of the thicknesses of all the lenses with refractive power on the optical axis. The following condition is satisfied: ΣTP=8.13899 mm and ΣTP/InTL=0.52477. Therefore, the contrast ratio of system imaging and the yield rate of lens manufacturing may be attended simultaneously. Moreover, an appropriate back focal length is provided to accommodate other elements.

In the optical image capturing module of the embodiment, R1 is the curvature radius of the object side surface 24112 of the sixth lens 2411. R2 is the curvature radius of the image side surface 24114 of the sixth lens 2411. The following condition is satisfied: |R1/R2|=8.99987. Therefore, the first lens 2411 is equipped with appropriate intensity of positive refractive power to prevent the spherical aberration from increasing too fast.

In the optical image capturing module of the embodiment, R11 is the curvature radius of the object side surface 24612 of the sixth lens 2461. R12 is the curvature radius of the image side surface 24614 of the sixth lens 2461. This following condition is satisfied: (R11−R12)/(R11+R12)=1.27780. Therefore, it is advantageous to correct the astigmatism generated by the optical image capturing module.

In the optical image capturing module of the embodiment, ΣPP is the sum of the focal lengths of all lenses with positive refractive power. The following conditions are satisfied: ΣPP=f2+f4+f5=69.770 mm and f5/(f2+f4+f5)=0.067. Therefore, it is beneficial to properly distribute the positive refractive power of a single lens to other positive lenses to suppress the generation of significant aberrations during the traveling of incident light.

In the optical image capturing module of the embodiment, ΣNP is the sum of the focal lengths of all lenses with negative refractive power. The following conditions are satisfied: ΣNP=f1+f3+f6=−38.451 mm and f6/(f1+f3+f6)=0.127. Therefore, it is beneficial to properly distribute the negative refractive power of the sixth lens 2461 to other negative lenses to suppress the generation of significant aberrations during the traveling of incident light.

In the optical image capturing module of the embodiment, IN 12 is the distance between the first lens 2411 and the second lens 2421 on the optical axis. The following condition is satisfied: IN12=6.418 mm; IN12/f=1.57491. Therefore, it is beneficial to improve the chromatic aberration of the lenses so as to enhance the performance.

In the optical image capturing module of the embodiment, IN56 is a distance between the fifth lens 2451 and the sixth lens 2461 on the optical axis. The following condition is satisfied: IN56=0.025 mm; IN56/f=0.00613. Therefore, it is beneficial to improve the chromatic aberration of the lenses so as to enhance the performance.

In the optical image capturing module of the embodiment, TP and TP2 are respectively the thicknesses of the first lens 2411 and the second lens 2421 on the optical axis. The following condition is satisfied: TP1=1.934 mm; TP2=2.486 mm; and (TP1+IN12)/TP2=3.36005. Therefore, it is beneficial to control the sensitivity produced by the optical image capturing module so as to enhance the performance.

In the optical image capturing module of the embodiment, TP5 and TP6 are respectively the thicknesses of the fifth lens 2451 and the sixth lens 2461 on the optical axis. IN56 is a distance between the two lenses on the optical axis. The following conditions are satisfied: TP5=1.072 mm; TP6=1.031 mm; (TP6+IN56)/TP5=0.98555. Therefore, it is beneficial to control the sensitivity produced by the optical image capturing module so as to enhance the performance.

In the optical image capturing module of the embodiment, IN34 is a distance between the third lens 2431 and the fourth lens 2441 on the optical axis. The following conditions are satisfied: IN34=0.401 mm; IN45=0.025 mm; and TP4/(IN34+TP4+IN45)=0.74376. Therefore, it is beneficial to slightly correct the aberration generated by the incident light advancing in the process layer upon layer so as to decrease the overall height of the system.

In the optical image capturing module of the embodiment, InRS51 is the horizontal distance parallel to an optical axis from a maximum effective half diameter position to an axial point on the object side surface 24512 of the fifth lens 2451. InRS62 is the horizontal distance parallel to an optical axis from a maximum effective half diameter position to an axial point on the image side surface 24514 of the fifth lens 2451. TP5 is the thickness of the fifth lens 2451 on the optical axis. The following condition is satisfied: InRS51=−0.34789 mm; InRS52=−0.88185 mm; |InRS51|/TP5=0.32458 and |InRS52|/TP5=0.82276.

In the optical image capturing module of the embodiment, HVT51 is the distance perpendicular to the optical axis between a critical point on an object side surface 24512 of the fifth lens 2451 and the optical axis. HVT52 is the distance perpendicular to the optical axis between a critical point on an image side surface 24514 of the fifth lens 2451 and the optical axis. The following conditions are satisfied: HVT51=0.515349 mm; HVT52=0 mm.

In the optical image capturing module of the embodiment, InRS61 is the horizontal distance parallel to an optical axis from a maximum effective half diameter position to an axial point on the object side surface 24612 of the sixth lens 2461. InRS62 is the horizontal distance parallel to an optical axis from a maximum effective half diameter position to an axial point on the image side surface 24614 of the sixth lens 2461. TP6 is the thickness of the sixth lens 2461 on the optical axis. The following conditions are satisfied: InRS61=−0.58390 mm; InRS62=0.41976 mm; |InRS61|/TP6=0.56616 and |InRS62|/TP6=0.40700. Therefore, it is advantageous for the lens to be manufactured and formed so as to maintain minimization.

In the optical image capturing module of the embodiment, HVT61 is the distance perpendicular to the optical axis between a critical point on an object side surface 24612 of the sixth lens 2461 and the optical axis. HVT62 is the distance perpendicular to the optical axis between a critical point on an image side surface 24614 of the sixth lens 2461 and the optical axis. The following conditions are satisfied: HVT61=0 mm; HVT62=0 mm.

In the optical image capturing module of the embodiment, the following conditions are satisfied: HVT51/HOI=0.1031. Therefore, it is beneficial to correct the aberration of surrounding view field for the optical image capturing module.

In the optical image capturing module of the embodiment, the following conditions are satisfied: HVT51/HOS=0.02634. Therefore, it is beneficial to correct the aberration of surrounding view field for the optical image capturing module.

In the optical image capturing module of the embodiment, the second lens 2421, the third lens 2431, and the sixth lens 2461 have negative refractive power. A dispersion coefficient of the second lens is NA2. A dispersion coefficient of the third lens is NA3. A dispersion coefficient of the sixth lens is NA6. The following condition is satisfied: NA6/NA2≤1. Therefore, it is beneficial to correct the aberration of the optical image capturing module.

In the optical image capturing module of the embodiment, TDT refers to TV distortion when an image is formed. ODT refers to optical distortion when an image is formed. The following conditions are satisfied: TDT=2.124%; ODT=5.076%.

In the optical image capturing module of the embodiment, LS is 12 mm. PhiA is 2*EHD62=6.726 mm (EHD62: the maximum effective half diameter of the image side 24614 of the sixth lens 2461). PhiC=PhiA+2*TH2=7.026 mm; PhiD=PhiC+2*(TH1+TH2)=7.426 mm; TH1 is 0.2 mm; TH2 is 0.15 mm; PhiA/PhiD is 0.9057; TH1+TH2 is 0.35 mm; (TH1+TH2)/HOI is 0.035; (TH1+TH2)/HOS is 0.0179; 2*(TH1+TH2)/PhiA is 0.1041; (TH1+TH2)/LS is 0.0292.

Please refer to Table 1 and Table 2 in the following.

TABLE 1 Data of the optical image capturing module of the first optical embodiment f = 4.075 mm; f/HEP = 1.4; HAF = 50.000 deg Surface Curvature Radius Thickness (mm) Material 0 Object Plano Plano 1 Lens 1 −40.99625704 1.934 Plastic 2 4.555209289 5.923 3 Aperture Plano 0.495 4 Lens 2 5.333427366 2.486 Plastic 5 −6.781659971 0.502 6 Lens 3 −5.697794287 0.380 Plastic 7 −8.883957518 0.401 8 Lens 4 13.19225664 1.236 Plastic 9 21.55681832 0.025 10 Lens 5 8.987806345 1.072 Plastic 11 −3.158875374 0.025 12 Lens 6 −29.46491425 1.031 Plastic 13 3.593484273 2.412 14 IR-cut filter Plano 0.200 15 Plano 1.420 16 Image plane Plano Surface Refractive index Dispersion coefficient Focal length 0 1 1.515 56.55 −7.828 2 3 4 1.544 55.96 5.897 5 6 1.642 22.46 −25.738 7 8 1.544 55.96 59.205 9 10 1.515 56.55 4.668 11 12 1.642 22.46 −4.886 13 14 1.517 64.13 15 16 Reference wavelength = 555 nm; Shield position: The clear aperture of the first surface is 5.800 mm. The clear aperture of the third surface is 1.570 mm. The clear aperture of the fifth surface is 1.950 mm.

Table 2. The Aspheric Surface Parameters of the First Optical Embodiment

TABLE 2 Aspheric Coefficients Surface 1 2 4 5 k 4.310876E+01 −4.707622E+00 2.616025E+00 2.445397E+00 A4 7.054243E−03 1.714312E−02 −8.377541E−03 −1.789549E−02 A6 −5.233264E−04 −1.502232E−04 −1.838068E−03 −3.657520E−03 A8 3.077890E−05 −1.359611E−04 1.233332E−03 −1.131622E−03 A10 −1.260650E−06 2.680747E−05 −2.390895E−03 1.390351E−03 A12 3.319093E−08 −2.017491E−06 1.998555E−03 −4.152857E−04 A14 −5.051600E−10 6.604615E−08 −9.734019E−04 5.487286E−05 A16 3.380000E−12 −1.301630E−09 2.478373E−04 −2.919339E−06 Surface 6 7 8 9 k 5.645686E+00 −2.117147E+01 −5.287220E+00 6.200000E+01 A4 −3.379055E−03 −1.370959E−02 −2.937377E−02 −1.359965E−01 A6 −1.225453E−03 6.250200E−03 2.743532E−03 6.628518E−02 A8 −5.979572E−03 −5.854426E−03 −2.457574E−03 −2.129167E−02 A10 4.556449E−03 4.049451E−03 1.874319E−03 4.396344E−03 A12 −1.177175E−03 −1.314592E−03 −6.013661E−04 −5.542899E−04 A14 1.370522E−04 2.143097E−04 8.792480E−05 3.768879E−05 A16 −5.974015E−06 −1.399894E−05 −4.770527E−06 −1.052467E−06 Surface 10 11 12 13 k −2.114008E+01 −7.699904E+00 −6.155476E+01 −3.120467E−01 A4 −1.263831E−01 −1.927804E−02 −2.492467E−02 −3.521844E−02 A6 6.965399E−02 2.478376E−03 −1.835360E−03 5.629654E−03 A8 −2.116027E−02 1.438785E−03 3.201343E−03 −5.466925E−04 A10 3.819371E−03 −7.013749E−04 −8.990757E−04 2.231154E−05 A12 −4.040283E−04 1.253214E−04 1.245343E−04 5.548990E−07 A14 2.280473E−05 −9.943196E−06 −8.788363E−06 −9.396920E−08 A16 −5.165452E−07 2.898397E−07 2.494302E−07 2.728360E−09

The values related to arc lengths may be obtained according to table 1 and table 2.

First optical embodiment (Reference wavelength = 555 nm) ARE ARE − 2(ARE/HEP) ARE/TP ARE 1/2(HEP) value 1/2(HEP) % TP (%) 11 1.455 1.455 −0.00033 99.98% 1.934 75.23% 12 1.455 1.495 0.03957 102.72% 1.934 77.29% 21 1.455 1.465 0.00940 100.65% 2.486 58.93% 22 1.455 1.495 0.03950 102.71% 2.486 60.14% 31 1.455 1.486 0.03045 102.09% 0.380 391.02% 32 1.455 1.464 0.00830 100.57% 0.380 385.19% 41 1.455 1.458 0.00237 100.16% 1.236 117.95% 42 1.455 1.484 0.02825 101.94% 1.236 120.04% 51 1.455 1.462 0.00672 100.46% 1.072 136.42% 52 1.455 1.499 0.04335 102.98% 1.072 139.83% 61 1.455 1.465 0.00964 100.66% 1.031 142.06% 62 1.455 1.469 0.01374 100.94% 1.031 142.45% ARS ARS/TP ARS EHD value ARS − EHD (ARS/EHD) % TP (%) 11 5.800 6.141 0.341 105.88% 1.934 317.51% 12 3.299 4.423 1.125 134.10% 1.934 228.70% 21 1.664 1.674 0.010 100.61% 2.486 67.35% 22 1.950 2.119 0.169 108.65% 2.486 85.23% 31 1.980 2.048 0.069 103.47% 0.380 539.05% 32 2.084 2.101 0.017 100.83% 0.380 552.87% 41 2.247 2.287 0.040 101.80% 1.236 185.05% 42 2.530 2.813 0.284 111.22% 1.236 227.63% 51 2.655 2.690 0.035 101.32% 1.072 250.99% 52 2.764 2.930 0.166 106.00% 1.072 273.40% 61 2.816 2.905 0.089 103.16% 1.031 281.64% 62 3.363 3.391 0.029 100.86% 1.031 328.83%

Table 1 is the detailed structure data to the first optical embodiment, wherein the unit of the curvature radius, the thickness, the distance, and the focal length is millimeters (mm). Surfaces 0-16 illustrate the surfaces from the object side to the image side. Table 2 is the aspheric coefficients of the first optical embodiment, wherein k is the conic coefficient in the aspheric surface formula. A1-A20 are aspheric surface coefficients from the first to the twentieth orders for each surface. In addition, the tables for each of the embodiments as follows correspond to the schematic views and the aberration graphs for each of the embodiments. The definitions of data in the tables are the same as those in Table 1 and Table 2 for the first optical embodiment. Therefore, similar description shall not be illustrated again. Furthermore, the definitions of element parameters in each of the embodiments are the same as those in the first optical embodiment.

The Second Optical Embodiment

As shown in FIG. 19, the auto-focus lens assembly 240 may include seven lenses 2401 with refractive power, which are a first lens 2411, a second lens 2421, a third lens 2431, a four lens 2441, a fifth lens 2451, a sixth lens 2461, and a seventh lens 2471 sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly 240 satisfies the following condition: 0.1≤InTL/HOS≤0.95. Specifically, HOS is the distance on the optical axis from an object side surface of the first lens 2411 to the image plane; InTL is the distance on the optical axis from an object side surface of the first lens 2411 to an image side surface of the seventh lens 2471.

Please refer to FIG. 22 and FIG. 23. FIG. 22 is a schematic diagram of the optical image capturing module according to the second optical embodiment of the present invention. FIG. 23 is a curve diagram of spherical aberration, astigmatism, and optical distortion of the optical image capturing module sequentially displayed from left to right according to the second optical embodiment of the present invention. As shown in FIG. 22, the optical image capturing module includes a first lens 2411, a second lens 2421, a third lens 2431, an aperture 250, a four lens 2441, a fifth lens 2451, a sixth lens 2461, a seventh lens 2471, an IR-cut filter 300, an image plane 600, and image sensor elements 140 sequentially displayed from an object side surface to an image side surface.

The first lens 2411 has negative refractive power and is made of a glass material. The object side surface 24112 thereof is a convex surface and the image side surface 24114 thereof is a concave surface.

The second lens 2421 has negative refractive power and is made of a glass material. The object side surface thereof 24212 is a concave surface and the image side surface thereof 24214 is a convex surface.

The third lens 2431 has positive refractive power and is made of a glass material. The object side surface 24312 thereof is a convex surface and the image side surface 24314 thereof is a convex surface.

The fourth lens 2441 has positive refractive power and is made of a glass material. The object side surface 24412 thereof is a convex surface and the image side surface 24414 thereof is a convex surface.

The fifth lens 2451 has positive refractive power and is made of a glass material. The object side surface 24512 thereof is a convex surface and the image side surface 24514 thereof is a convex surface.

The sixth lens 2461 has negative refractive power and is made of a glass material. The object side surface 24612 thereof is a concave surface and the image side surface 24614 thereof is a concave surface. Therefore, it may be effective to adjust the angle at which each field of view is incident on the sixth lens 2461 to improve the aberration.

The seventh lens 2471 has positive refractive power and is made of a glass material. The object side surface 24712 thereof is a convex surface and the image side surface 24714 thereof is a convex surface. Therefore, it is advantageous for the lens to reduce the back focal length to maintain minimization.

The IR-cut filter 300 is made of glass and is disposed between the seventh lens 2471 and the image plane 600, which does not affect the focal length of the optical image capturing module.

Please refer to the following Table 3 and Table 4.

TABLE 3 Data of the optical image capturing module of the second optical embodiment f = 4.7601 mm; f/HEP = 2.2; HAF = 95.98 deg Surface Curvature Radius Thickness (mm) Material 0 Object 1E+18 1E+18 1 Lens 1 47.71478323 4.977 Glass 2 9.527614761 13.737 3 Lens 2 −14.88061107 5.000 Glass 4 −20.42046946 10.837 5 Lens 3 182.4762997 5.000 Glass 6 −46.71963608 13.902 7 Aperture 1E+18 0.850 8 Lens 4 28.60018103 4.095 Glass 9 −35.08507586 0.323 10 Lens 5 18.25991342 1.539 Glass 11 −36.99028878 0.546 12 Lens 6 −18.24574524 5.000 Glass 13 15.33897192 0.215 14 Lens 7 16.13218937 4.933 Glass 15 −11.24007 8.664 16 IR-cut filter 1E+18 1.000 BK_7 17 1E+18 1.007 18 Image plane 1E+18 −0.007 Surface Refractive index Dispersion coefficient Focal length 0 1 2.001 29.13 −12.647 2 3 2.001 29.13 −99.541 4 5 1.847 23.78 44.046 6 7 8 1.834 37.35 19.369 9 10 1.609 46.44 20.223 11 12 2.002 19.32 −7.668 13 14 1.517 64.20 13.620 15 16 1.517 64.2 17 18 Reference Wavelength = 555 nm

Table 4. The Aspheric Surface Parameters of the Second Optical Embodiment

TABLE 4 Aspheric Coefficients Surface 1 2 3 4 k 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A4 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A6 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A8 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A10 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A12 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 Surface 5 6 8 9 k 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A4 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A6 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A8 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A10 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A12 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 Surface 10 11 12 13 k 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A4 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A6 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A8 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A10 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A12 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 Surface 14 15 k 0.000000E+00 0.000000E+00 A4 0.000000E+00 0.000000E+00 A6 0.000000E+00 0.000000E+00 A8 0.000000E+00 0.000000E+00 A10 0.000000E+00 0.000000E+00 A12 0.000000E+00 0.000000E+00

In the second optical embodiment, the aspheric surface formula is presented in the same way in the first optical embodiment. In addition, the definitions of parameters in following tables are the same as those in the first optical embodiment. Therefore, similar description shall not be illustrated again.

The values stated as follows may be deduced according to Table 3 and Table 4.

The second optical embodiment (Primary reference wavelength: 555 nm) |f/f1| |f/f2| |f/f3| |f/f4| |f/f5| |f/f6| 0.3764 0.0478 0.1081 0.2458 0.2354 0.6208 |f/f7| ΣPPR ΣNPR ΣPPR/ IN12/f IN67/f |ΣNPR| 0.3495 1.3510 0.6327 2.1352 2.8858 0.0451 |f1/f2| |f2/f3| (TP1 + IN12)/TP2 (TP7 + IN67)/TP6 0.1271 2.2599 3.7428 1.0296 HOS InTL HOS/HOI InS/HOS ODT % TDT % 81.6178 70.9539 13.6030 0.3451 −113.2790 84.4806 HVT11 HVT12 HVT21 HVT22 HVT31 HVT32 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 HVT61 HVT62 HVT71 HVT72 HVT72/HOI HVT72/ HOS 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 PhiA PhiC PhiD TH1 TH2 HOI 11.962 mm 12.362 mm 12.862 mm 0.25 mm 0.2 mm 6 mm PhiA/ TH1 + TH2 (TH1 + TH2)/ (TH1 + TH2)/ 2(TH1 + TH2)/ InTL/HOS PhiD HOI HOS PhiA 0.9676 0.45 mm 0.075 0.0055 0.0752 0.8693 PSTA PLTA NSTA NLTA SSTA SLTA 0.060 mm −0.005 mm 0.016 mm 0.006 mm 0.020 mm −0.008 mm

The values stated as follows may be deduced according to Table 3 and Table 4.

The second optical embodiment (Primary reference wavelength: 555 nm) ARE ARE − 2(ARE/HEP) ARE/TP ARE 1/2(HEP) value 1/2(HEP) % TP (%) 11 1.082 1.081 −0.00075 99.93% 4.977 21.72% 12 1.082 1.083 0.00149 100.14% 4.977 21.77% 21 1.082 1.082 0.00011 100.01% 5.000 21.64% 22 1.082 1.082 −0.00034 99.97% 5.000 21.63% 31 1.082 1.081 −0.00084 99.92% 5.000 21.62% 32 1.082 1.081 −0.00075 99.93% 5.000 21.62% 41 1.082 1.081 −0.00059 99.95% 4.095 26.41% 42 1.082 1.081 −0.00067 99.94% 4.095 26.40% 51 1.082 1.082 −0.00021 99.98% 1.539 70.28% 52 1.082 1.081 −0.00069 99.94% 1.539 70.25% 61 1.082 1.082 −0.00021 99.98% 5.000 21.63% 62 1.082 1.082 0.00005 100.00% 5.000 21.64% 71 1.082 1.082 −0.00003 100.00% 4.933 21.93% 72 1.082 1.083 0.00083 100.08% 4.933 21.95% ARS ARS − ARS/TP ARS EHD value EHD (ARS/EHD) % TP (%) 11 20.767 21.486 0.719 103.46% 4.977 431.68% 12 9.412 13.474 4.062 143.16% 4.977 270.71% 21 8.636 9.212 0.577 106.68% 5.000 184.25% 22 9.838 10.264 0.426 104.33% 5.000 205.27% 31 8.770 8.772 0.003 100.03% 5.000 175.45% 32 8.511 8.558 0.047 100.55% 5.000 171.16% 41 4.600 4.619 0.019 100.42% 4.095 112.80% 42 4.965 4.981 0.016 100.32% 4.095 121.64% 51 5.075 5.143 0.067 101.33% 1.539 334.15% 52 5.047 5.062 0.015 100.30% 1.539 328.89% 61 5.011 5.075 0.064 101.28% 5.000 101.50% 62 5.373 5.489 0.116 102.16% 5.000 109.79% 71 5.513 5.625 0.112 102.04% 4.933 114.03% 72 5.981 6.307 0.326 105.44% 4.933 127.84%

The values stated as follows may be deduced according to Table 3 and Table 4.

Related inflection point values of second optical embodiment (Primary reference wavelength: 555 nm) HIF111 0 HIF111/HOI 0 SGI111 0 |SGI111|/ 0 (|SGI111| + TP1)

The Third Optical Embodiment

As shown in FIG. 18, the auto-focus lens assembly 240 may include six lenses 2401 with refractive power, which are a first lens 2411, a second lens 2421, a third lens 2431, a four lens 2441, a fifth lens 2451, and a sixth lens 2461 sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly 240 satisfies the following condition: 0.1≤InTL/HOS≤0.95. Specifically, HOS is the distance from an object side surface of the first lens 2411 to the imaging surface on an optical axis. InTL is the distance on the optical axis from an object side surface of the first lens 2411 to an image side surface of the sixth lens 2461.

Please refer to FIG. 24 and FIG. 25. FIG. 24 is a schematic diagram of the optical image capturing module according to the third optical embodiment of the present invention. FIG. 25 is a curve diagram of spherical aberration, astigmatism, and optical distortion of the optical image capturing module sequentially displayed from left to right according to the third optical embodiment of the present invention. As shown in FIG. 24, the optical image capturing module includes a first lens 2411, a second lens 2421, a third lens 2431, an aperture 250, a four lens 2441, a fifth lens 2451, a sixth lens 2461, an IR-cut filter 300, an image plane 600, and image sensor elements 140 sequentially displayed from an object side surface to an image side surface.

The first lens 2411 has negative refractive power and is made of a glass material. The object side surface 24112 thereof is a convex surface and the image side surface 24114 thereof is a concave surface, both of which are spherical.

The second lens 2421 has negative refractive power and is made of a glass material. The object side surface thereof 24212 is a concave surface and the image side surface thereof 24214 is a convex surface, both of which are spherical.

The third lens 2431 has positive refractive power and is made of a glass material. The object side surface 24312 thereof is a convex surface and the image side surface 24314 thereof is a convex surface, both of which are aspheric. The object side surface 334 thereof has an inflection point.

The fourth lens 2441 has negative refractive power and is made of a plastic material. The object side surface thereof 24412 is a concave surface and the image side surface thereof 24414 is a concave surface, both of which are aspheric. The image side surface 24414 thereof both have an inflection point.

The fifth lens 2451 has positive refractive power and is made of a plastic material. The object side surface 24512 thereof is a convex surface and the image side surface 24514 thereof is a convex surface, both of which are aspheric.

The sixth lens 2461 has negative refractive power and is made of a plastic material. The object side surface 24612 thereof is a convex surface and the image side surface 24614 thereof is a concave surface. The object side surface 24612 and the image side surface 24614 thereof both have an inflection point. Therefore, it is advantageous for the lens to reduce the back focal length to maintain minimization. In addition, it is effective to suppress the incident angle with incoming light from an off-axis view field and further correct the aberration in the off-axis view field.

The IR-cut filter 300 is made of glass and is disposed between the sixth lens 2461 and the image plane 600, which does not affect the focal length of the optical image capturing module.

Please refer to the following Table 5 and Table 6.

TABLE 5 Data of the optical image capturing module of the third optical embodiment f = 2.808 mm; f/HEP = 1.6; HAF = 100 deg Surface Curvature radius Thickness (mm) Material 0 Object 1E+18 1E+18 1 Lens 1 71.398124 7.214 Glass 2 7.117272355 5.788 3 Lens 2 −13.29213699 10.000 Glass 4 −18.37509887 7.005 5 Lens 3 5.039114804 1.398 Plastic 6 −15.53136631 −0.140 7 Aperture 1E+18 2.378 8 Lens 4 −18.68613609 0.577 Plastic 9 4.086545927 0.141 10 Lens 5 4.927609282 2.974 Plastic 11 −4.551946605 1.389 12 Lens 6 9.184876531 1.916 Plastic 13 4.845500046 0.800 14 IR-cut filter 1E+18 0.500 BK_7 15 1E+18 0.371 16 image plane 1E+18 0.005 Surface Refractive Index Dispersion coefficient Focal length 0 1 1.702 41.15 −11.765 2 3 2.003 19.32 −4537.460 4 5 1.514 56.80 7.553 6 7 8 1.661 20.40 −4.978 9 10 1.565 58.00 4.709 11 12 1.514 56.80 −23.405 13 14 1.517 64.13 15 16 Reference wavelength (d-line) = 555 nm

Table 6. The Aspheric Surface Parameters of the Third Optical Embodiment

TABLE 6 Aspheric Coefficients Surface No 1 2 3 4 k 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A4 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A6 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A8 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A10 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 Surface No 5 6 8 9 k 1.318519E−01 3.120384E+00 −1.494442E+01 2.744228E−02 A4 6.405246E−05 2.103942E−03 −1.598286E−03 −7.291825E−03 A6 2.278341E−05 −1.050629E−04 −9.177115E−04 9.730714E−05 A8 −3.672908E−06 6.168906E−06 1.011405E−04 1.101816E−06 A10 3.748457E−07 −1.224682E−07 −4.919835E−06 −6.849076E−07 Surface No 10 11 12 13 k −7.864013E+00 −2.263702E+00 −4.206923E+01 −7.030803E+00 A4 1.405243E−04 −3.919567E−03 −1.679499E−03 −2.640099E−03 A6 1.837602E−04 2.683449E−04 −3.518520E−04 −4.507651E−05 A8 −2.173368E−05 −1.229452E−05 5.047353E−05 −2.600391E−05 A10 7.328496E−07 4.222621E−07 −3.851055E−06 1.161811E−06 In the third optical embodiment, the aspheric surface formula is presented in the same way in the first optical embodiment. In addition, the definitions of parameters in following tables are the same as those in the first optical embodiment. Therefore, similar description shall not be illustrated again.

The values stated as follows may be deduced according to Table 5 and Table 6.

Third optical embodiment (Primary reference wavelength: 555 nm) |f/f1| |f/f2| |f/f3| |f/f4| |f/f5| |f/f6| 0.23865 0.00062 0.37172 0.56396 0.59621 0.11996 ΣPPR ΣNPR ΣPPR/ IN12/f IN56/f TP4/ |ΣNPR| (IN34 + TP4 + IN45) 1.77054 0.12058 14.68400 2.06169 0.49464 0.19512 |f1/f2| |f2/f3| (TP1 + IN12)/TP2 (TP6 + IN56)/TP5 0.00259 600.74778 1.30023 1.11131 HOS InTL HOS/HOI InS/HOS ODT % TDT % 42.31580 40.63970 10.57895 0.26115 −122.32700 93.33510 HVT51 HVT52 HVT61 HVT62 HVT62/HOI HVT62/HOS 0 0 2.22299 2.60561 0.65140 0.06158 TP2/ TP3/ InRS61 InRS62 |InRS61|/ |InRS62|/TP6 TP3 TP4 TP6 7.15374 2.42321 −0.20807 −0.24978 0.10861 0.13038 PhiA PhiC PhiD TH1 TH2 HOI 6.150 mm 6.41 mm 6.71 mm 0.15 mm 0.13 mm 4 mm PhiA/ TH1 + TH2 (TH1 + TH2)/ (TH1 + TH2)/ 2(TH1 + TH2)/ InTL/HOS PhiD HOI HOS PhiA 0.9165 0.28 mm 0.07 0.0066 0.0911 0.9604 PSTA PLTA NSTA NLTA SSTA SLTA 0.014 mm 0.002 mm −0.003 mm −0.002 mm 0.011 mm −0.001 mm

The values related to arc lengths may be obtained according to table 5 and table 6.

Third optical embodiment (Reference wavelength = 555 nm) ARE ARE − 2(ARE/HEP) ARE/TP ARE 1/2(HEP) value 1/2(HEP) % TP (%) 11 0.877 0.877 −0.00036 99.96% 7.214 12.16% 12 0.877 0.879 0.00186 100.21% 7.214 12.19% 21 0.877 0.878 0.00026 100.03% 10.000 8.78% 22 0.877 0.877 −0.00004 100.00% 10.000 8.77% 31 0.877 0.882 0.00413 100.47% 1.398 63.06% 32 0.877 0.877 0.00004 100.00% 1.398 62.77% 41 0.877 0.877 −0.00001 100.00% 0.577 152.09% 42 0.877 0.883 0.00579 100.66% 0.577 153.10% 51 0.877 0.881 0.00373 100.43% 2.974 29.63% 52 0.877 0.883 0.00521 100.59% 2.974 29.68% 61 0.877 0.878 0.00064 100.07% 1.916 45.83% 62 0.877 0.881 0.00368 100.42% 1.916 45.99% ARS ARS − ARS/TP ARS EHD value EHD (ARS/EHD) % TP (%) 11 17.443 17.620 0.178 101.02% 7.214 244.25% 12 6.428 8.019 1.592 124.76% 7.214 111.16% 21 6.318 6.584 0.266 104.20% 10.000 65.84% 22 6.340 6.472 0.132 102.08% 10.000 64.72% 31 2.699 2.857 0.158 105.84% 1.398 204.38% 32 2.476 2.481 0.005 100.18% 1.398 177.46% 41 2.601 2.652 0.051 101.96% 0.577 459.78% 42 3.006 3.119 0.113 103.75% 0.577 540.61% 51 3.075 3.171 0.096 103.13% 2.974 106.65% 52 3.317 3.624 0.307 109.24% 2.974 121.88% 61 3.331 3.427 0.095 102.86% 1.916 178.88% 62 3.944 4.160 0.215 105.46% 1.916 217.14%

The values stated as follows may be deduced according to Table 5 and Table 6.

Related inflection point values of third optical embodiment (Primary reference wavelength: 555 nm) HIF321 2.0367 HIF321/ 0.5092 SGI321 −0.1056 |SGI321|/ 0.0702 HOI (|SGI321| + TP3) HIF421 2.4635 HIF421/ 0.6159 SGI421 0.5780 |SGI421|/ 0.5005 HOI (|SGI421| + TP4) HIF611 1.2364 HIF611/ 0.3091 SGI611 0.0668 |SGI611|/ 0.0337 HOI (|SGI611| + TP6) HIF621 1.5488 HIF621/ 0.3872 SGI621 0.2014 |SGI621|/ 0.0951 HOI (|SGI621| + TP6)

The Fourth Optical Embodiment

As shown in FIG. 17, the auto-focus lens assembly 240 may include five lenses 2401 with refractive power, which are a first lens 2411, a second lens 2421, a third lens 2431, a four lens 2441, a fifth lens 2451 sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly 240 satisfies the following condition: 0.1≤InTL/HOS≤0.95. Specifically, HOS is the distance on the optical axis from an object side surface of the first lens 2411 to the image plane; InTL is the distance on the optical axis from an object side surface of the first lens 2411 to an image side surface of the fifth lens 2451.

Please refer to FIG. 26 and FIG. 27. FIG. 26 is a schematic diagram of the optical image capturing module according to the fourth optical embodiment of the present invention. FIG. 27 is a curve diagram of spherical aberration, astigmatism, and optical distortion of the optical image capturing module sequentially displayed from left to right according to the fourth optical embodiment of the present invention. As shown in FIG. 26, the optical image capturing module includes a first lens 2411, a second lens 2421, a third lens 2431, an aperture 250, a four lens 2441, a fifth lens 2451, a sixth lens 2461, an IR-cut filter 300, an image plane 600, and image sensor elements 140 sequentially displayed from an object side surface to an image side surface.

The first lens 2411 has negative refractive power and is made of a glass material. The object side surface 24112 thereof is a convex surface and the image side surface 24114 thereof is a concave surface, both of which are spherical.

The second lens 2421 has negative refractive power and is made of a plastic material. The object side surface thereof 24212 is a concave surface and the image side surface thereof 24214 is a concave surface, both of which are aspheric. The object side surface 24212 has an inflection point.

The third lens 2431 has positive refractive power and is made of a plastic material. The object side surface 24312 thereof is a convex surface and the image side surface 24314 thereof is a convex surface, both of which are aspheric. The object side surface 24312 thereof has an inflection point.

The fourth lens 2441 has positive refractive power and is made of a plastic material. The object side surface 24412 thereof is a convex surface and the image side surface 24414 thereof is a concave surface, both of which are aspheric. The object side surface 24412 thereof has an inflection point.

The fifth lens 2451 has negative refractive power and is made of a plastic material. The object side surface thereof 24512 is a concave surface and the image side surface thereof 24514 is a concave surface, both of which are aspheric. The object side surface 24512 has two inflection points. Therefore, it is advantageous for the lens to reduce the back focal length to maintain minimization.

The IR-cut filter 300 is made of glass and is disposed between the fifth lens 2451 and the image plane 600, which does not affect the focal length of the optical image capturing module.

Please refer to the following Table 7 and Table 8.

TABLE 7 Data of the optical image capturing module of the fourth optical embodiment f = 2.7883 mm; f/HEP = 1.8; HAF = 101 deg Surface Curvature radius Thickness (mm) Material 0 Object 1E+18 1E+18 1 Lens 1 76.84219 6.117399 Glass 2 12.62555 5.924382 3 Lens 2 −37.0327 3.429817 Plastic 4 5.88556 5.305191 5 Lens 3 17.99395 14.79391 6 −5.76903 −0.4855 Plastic 7 Aperture 1E+18 0.535498 8 Lens 4 8.19404 4.011739 Plastic 9 −3.84363 0.050366 10 Lens 5 −4.34991 2.088275 Plastic 11 16.6609 0.6 12 IR-cut filter 1E+18 0.5 BK_7 13 1E+18 3.254927 14 Image plane 1E+18 −0.00013 Surface Refractive index Dispersion coefficient Focal length 0 1 1.497 81.61 −31.322 2 3 1.565 54.5 −8.70843 4 5 6 1.565 58 9.94787 7 8 1.565 58 5.24898 9 10 1.661 20.4 −4.97515 11 12 1.517 64.13 13 14 Reference wavelength(d-line) = 555 nm

Table 8. The Aspheric Surface Parameters of the Fourth Optical Embodiment

TABLE 8 Aspheric Coefficients Surface 1 2 3 4 k 0.000000E+00 0.000000E+00 0.131249 −0.069541 A4 0.000000E+00 0.000000E+00   3.99823E−05 −8.55712E−04 A6 0.000000E+00 0.000000E+00   9.03636E−08 −1.96175E−06 A8 0.000000E+00 0.000000E+00   1.91025E−09 −1.39344E−08 A10 0.000000E+00 0.000000E+00 −1.18567E−11 −4.17090E−09 A12 0.000000E+00 0.000000E+00  0.000000E+00 0.000000E+00 Surface 5 6 8 9 k −0.324555 0.009216 −0.292346 −0.18604 A4 −9.07093E−04   8.80963E−04 −1.02138E−03   4.33629E−03 A6 −1.02465E−05   3.14497E−05 −1.18559E−04 −2.91588E−04 A8 −8.18157E−08 −3.15863E−06  1.34404E−05   9.11419E−06 A10 −2.42621E−09   1.44613E−07 −2.80681E−06   1.28365E−07 A12  0.000000E+00  0.000000E+00  0.000000E+00  0.000000E+00 Surface 10 11 k −6.17195 27.541383 A4   1.58379E−03   7.56932E−03 A6 −1.81549E−04 −7.83858E−04 A8 −1.18213E−05   4.79120E−05 A10   1.92716E−06 −1.73591E−06 A12  0.000000E+00  0.000000E+00

In the fourth optical embodiment, the aspheric surface formula is presented in the same way in the first optical embodiment. In addition, the definitions of parameters in following tables are the same as those in the first optical embodiment. Therefore, similar description shall not be illustrated again.

The values stated as follows may be deduced according to Table 7 and Table 8.

Fourth optical embodiment (Primary reference wavelength: 555 nm) |f/f1| |f/f2| |f/f3| |f/f4| |f/f5| |f1/f2| 0.08902 0.32019 0.28029 0.53121 0.56045 3.59674 ΣPPR ΣNPR ΣPPR/ IN12/f IN45/f |f2/f3| |ΣNPR| 1.4118 0.3693 3.8229 2.1247 0.0181 0.8754 TP3/ (TP1 + IN12)/TP2 (TP5 + IN45)/TP4 (IN23 + TP3 + IN34) 0.73422 3.51091 0.53309 HOS InTL HOS/HOI InS/HOS ODT % TDT % 46.12590 41.77110 11.53148 0.23936 −125.266 99.1671 HVT41 HVT42 HVT51 HVT52 HVT52/HOI HVT52/ HOS 0.00000 0.00000 0.00000 0.00000 0.00000 0.00000 TP2/ TP3/TP4 InRS51 InRS52 |InRS51|/ |InRS52|/ TP3 TP5 TP5 0.23184 3.68765 −0.679265 0.5369 0.32528 0.25710 PhiA PhiC PhiD TH1 TH2 HOI 5.598 mm 5.858 mm 6.118 mm 0.13 mm 0.13 mm 4 mm PhiA/ TH1 + TH2 (TH1 + TH2)/ (TH1 + TH2)/ 2(TH1 + TH2)/ InTL/HOS PhiD HOI HOS PhiA 0.9150 0.26 mm 0.065 0.0056 0.0929 0.9056 PSTA PLTA NSTA NLTA SSTA SLTA −0.011 mm 0.005 mm −0.010 mm −0.003 mm 0.005 mm −0.00026 mm

The values related to arc lengths may be obtained according to table 7 and table 8.

Fourth optical embodiment (Reference wavelength = 555 nm) ARE ARE − 2(ARE/HEP) ARE/TP ARE 1/2(HEP) value 1/2(HEP) % TP (%) 11 0.775 0.774 −0.00052 99.93% 6.117 12.65% 12 0.775 0.774 −0.00005 99.99% 6.117 12.66% 21 0.775 0.774 −0.00048 99.94% 3.430 22.57% 22 0.775 0.776 0.00168 100.22% 3.430 22.63% 31 0.775 0.774 −0.00031 99.96% 14.794 5.23% 32 0.775 0.776 0.00177 100.23% 14.794 5.25% 41 0.775 0.775 0.00059 100.08% 4.012 19.32% 42 0.775 0.779 0.00453 100.59% 4.012 19.42% 51 0.775 0.778 0.00311 100.40% 2.088 37.24% 52 0.775 0.774 −0.00014 99.98% 2.088 37.08% ARS ARS − ARS/TP ARS EHD value EHD (ARS/EHD) % TP (%) 11 23.038 23.397 0.359 101.56% 6.117 382.46% 12 10.140 11.772 1.632 116.10% 6.117 192.44% 21 10.138 10.178 0.039 100.39% 3.430 296.74% 22 5.537 6.337 0.800 114.44% 3.430 184.76% 31 4.490 4.502 0.012 100.27% 14.794 30.43% 32 2.544 2.620 0.076 102.97% 14.794 17.71% 41 2.735 2.759 0.024 100.89% 4.012 68.77% 42 3.123 3.449 0.326 110.43% 4.012 85.97% 51 2.934 3.023 0.089 103.04% 2.088 144.74% 52 2.799 2.883 0.084 103.00% 2.088 138.08%

The values stated as follows may be deduced according to Table 7 and Table 8.

Related inflection point values of fourth optical embodiment (Primary reference wavelength: 555 nm) HIF211 6.3902 HIF211/ 1.5976 SGI211 −0.4793 |SGI211|/ 0.1226 HOI (|SGI211| + TP2) HIF311 2.1324 HIF311/ 0.5331 SGI311 0.1069 |SGI311|/ 0.0072 HOI (|SGI311| + TP3) HIF411 2.0278 HIF411/ 0.5070 SGI411 0.2287 |SGI411|/ 0.0539 HOI (|SGI411| + TP4) HIF511 2.6253 HIF511/ 0.6563 SGI511 −0.5681 |SGI511|/ 0.2139 HOI (|SGI511| + TP5) HIF512 2.1521 HIF512/ 0.5380 SGI512 −0.8314 |SGI512|/ 0.2848 HOI (|SGI512| + TP5)

The Fifth Optical Embodiment

As shown in FIG. 16, the auto-focus lens assembly 240 may include fourth lenses with refractive power, which are a first lens 2411, a second lens 2421, a third lens 2431, and a four lens 2441 sequentially displayed from an object side surface to an image side surface. The auto-focus lens assembly 240 satisfies the following condition: 0.1≤InTL/HOS≤0.95. Specifically, HOS is the distance on the optical axis from an object side surface of the first lens 2411 to the image plane; InTL is the distance on the optical axis from an object side surface of the first lens 2411 to an image side surface of the fourth lens 2441.

Please refer to FIG. 28 and FIG. 29. FIG. 28 is a schematic diagram of the optical image capturing module according to the fifth optical embodiment of the present invention. FIG. 29 is a curve diagram of spherical aberration, astigmatism, and optical distortion of the optical image capturing module sequentially displayed from left to right according to the fifth optical embodiment of the present invention. As shown in FIG. 28, the optical image capturing module includes an aperture 250, a first lens 2411, a second lens 2421, a third lens 2431, a four lens 2441, an IR-cut filter 300, an image plane 600, and image sensor elements 140 sequentially displayed from an object side surface to an image side surface.

The first lens 2411 has positive refractive power and is made of a plastic material. The object side surface 24112 thereof is a convex surface and the image side surface 24114 thereof is a convex surface, both of which are aspheric. The object side surface 24112 thereof has an inflection point.

The second lens 2421 has negative refractive power and is made of a plastic material. The object side surface thereof 24212 is a convex surface and the image side surface thereof 24214 is a concave surface, both of which are aspheric. The object side surface 24212 has two inflection points and the image side surface 24214 thereof has an inflection point.

The third lens 2431 has positive refractive power and is made of a plastic material. The object side surface 24312 thereof is a concave surface and the image side surface 24314 thereof is a convex surface, both of which are aspheric. The object side surface 24312 thereof has three inflection points and the image side surface 24314 thereof has an inflection point.

The fourth lens 2441 has negative refractive power and is made of a plastic material. The object side surface thereof 24412 is a concave surface and the image side surface thereof 24414 is a concave surface, both of which are aspheric. The object side surface thereof 24412 has two inflection points and the image side surface 24414 thereof has an inflection point.

The IR-cut filter 300 is made of glass and is disposed between the fourth lens 2441 and the image plane 600, which does not affect the focal length of the optical image capturing module.

Please refer to the following Table 9 and Table 10.

TABLE 9 Data of the optical image capturing module of the fifth optical embodiment f = 1.04102 mm; f/HEP = 1.4; HAF = 44.0346 deg Surface Curvature Radius Thickness (mm) Material 0 Object 1E+18 600 1 Aperture 1E+18 −0.020 2 Lens 1 0.890166851 0.210 Plastic 3 −29.11040115 −0.010 4 1E+18 0.116 5 Lens 2 10.67765398 0.170 Plastic 6 4.977771922 0.049 7 Lens 3 −1.191436932 0.349 Plastic 8 −0.248990674 0.030 9 Lens 4 −38.08537212 0.176 Plastic 10 0.372574476 0.152 11 IR-cut filter 1E+18 0.210 BK_7 12 1E+18 0.185 13 Image plane 1E+18 0.005 Surface Refractive index Dispersion coefficient Focal length 0 1 2 1.545 55.96 1.587 3 4 5 1.642 22.46 −14.569 6 7 1.545 55.96 0.510 8 9 1.642 22.46 −0.569 10 11 1.517 64.13 12 13 Reference wavelength (d-line) = 555 nm. Shield position: The radius of the clear aperture of the fourth surface is 0.360 mm.

Table 10. The Aspheric Surface Parameters of the Fifth Optical Embodiment

TABLE 10 Aspheric Coefficients Surface 2 3 5 6 k = −1.106629E+00 2.994179E−07 −7.788754E+01 −3.440335E+01 A4= 8.291155E−01 −6.401113E−01 −4.958114E+00 −1.875957E+00 A6= −2.398799E+01 −1.265726E+01 1.299769E+02 8.568480E+01 A8 = 1.825378E+02 8.457286E+01 −2.736977E+03 −1.279044E+03 A10= −6.211133E+02 −2.157875E+02 2.908537E+04 8.661312E+03 A12= −4.719066E+02 −6.203600E+02 −1.499597E+05 −2.875274E+04 A14= 0.000000E+00 0.000000E+00 2.992026E+05 3.764871E+04 A16= 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A18= 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 A20= 0.000000E+00 0.000000E+00 0.000000E+00 0.000000E+00 Surface 7 8 9 10 k= −8.522097E−01 −4.735945E+00 −2.277155E+01 −8.039778E−01 A4= −4.878227E−01 −2.490377E+00 1.672704E+01 −7.613206E+00 A6= 1.291242E+02 1.524149E+02 −3.260722E+02 3.374046E+01 A8 = −1.979689E+03 −4.841033E+03 3.373231E+03 −1.368453E+02 A10= 1.456076E+04 8.053747E+04 −2.177676E+04 4.049486E+02 A12= −5.975920E+04 −7.936887E+05 8.951687E+04 −9.711797E+02 A14= 1.351676E+05 4.811528E+06 −2.363737E+05 1.942574E+03 A16= −1.329001E+05 −1.762293E+07 3.983151E+05 −2.876356E+03 A18= 0.000000E+00 3.579891E+07 −4.090689E+05 2.562386E+03 A20= 0.000000E+00 −3.094006E+07 2.056724E+05 −9.943657E+02

In the fifth optical embodiment, the aspheric surface formula is presented in the same way in the first optical embodiment. In addition, the definitions of parameters in following tables are the same as those in the first optical embodiment. Therefore, similar description shall not be illustrated again.

The values stated as follows may be deduced according to Table 9 and Table 10.

Fifth optical embodiment (Primary reference wavelength: 555 nm) InRS41 InRS42 HVT41 HVT42 ODT % TDT % −0.07431 0.00475 0.00000 0.53450 2.09403 0.84704 |f/f1| |f/f2| |f/f3| |f/f4| |f1/f2| |f2/f3| 0.65616 0.07145 2.04129 1.83056 0.10890 28.56826 ΣPPR ΣNPR ΣPPR/ ΣPP ΣNP f1/ΣPP |ΣNPR| 2.11274 2.48672 0.84961 −14.05932 1.01785 1.03627 f4/ΣNP IN12/f IN23/f IN34/f TP3/f TP4/f 1.55872 0.10215 0.04697 0.02882 0.33567 0.16952 InTL HOS HOS/HOI InS/HOS InTL/HOS ΣTP/ InTL 1.09131 1.64329 1.59853 0.98783 0.66410 0.83025 (TP1 + IN12)/ (TP4 + IN34)/ TP1/TP2 TP3/TP4 IN23/(TP2 + IN23 + TP3) TP2 TP3 1.86168 0.59088 1.23615 1.98009 0.08604 |InRS41|/ |InRS42|/ HVT42/HOI HVT42/ InTL/HOS TP4 TP4 HOS 0.4211 0.0269 0.5199 0.3253 0.6641 PhiA PhiC PhiD TH1 TH2 HOI 1.596 mm 1.996 mm 2.396 mm 0.2 mm 0.2 mm 1.028 mm PhiA/PhiD TH1 + TH2 (TH1 + TH2)/ (TH1 + TH2)/ 2(TH1 + TH2)/ HOI HOS PhiA 0.7996 0.4 mm 0.3891 0.2434 0.5013 PSTA PLTA NSTA NLTA SSTA SLTA −0.029 mm −0.023 mm −0.011 mm −0.024 mm 0.010 mm 0.011 mm

The values stated as follows may be deduced according to Table 9 and Table 10.

Related inflection point values of fifth optical embodiment (Primary reference wavelength: 555 nm) HIF111 0.28454 HIF111/ 0.27679 SGI111 0.04361 |SGI111|/ 0.17184 HOI (|SGI111| + TP1) HIF211 0.04198 HIF211/ 0.04083 SGI211 0.00007 |SGI211|/ 0.00040 HOI (|SGI211| + TP2) HIF212 0.37903 HIF212/ 0.36871 SGI212 −0.03682 |SGI212|/ 0.17801 HOI (|SGI212| + TP2) HIF221 0.25058 HIF221/ 0.24376 SGI221 0.00695 |SGI221|/ 0.03927 HOI (|SGI221| + TP2) HIF311 0.14881 HIF311/ 0.14476 SGI311 −0.00854 |SGI311|/ 0.02386 HOI (|SGI311| + TP3) HIF312 0.31992 HIF312/ 0.31120 SGI312 −0.01783 |SGI312|/ 0.04855 HOI (|SGI312| + TP3) HIF313 0.32956 HIF313/ 0.32058 SGI313 −0.01801 |SGI313|/ 0.04902 HOI (|SGI313| + TP3) HIF321 0.36943 HIF321/ 0.35937 SGI321 −0.14878 |SGI321|/ 0.29862 HOI (|SGI321| + TP3) HIF411 0.01147 HIF411/ 0.01116 SGI411 −0.00000 |SGI411|/ 0.00001 HOI (|SGI411| + TP4) HIF412 0.22405 HIF412/ 0.21795 SGI412 0.01598 |SGI412|/ 0.08304 HOI (|SGI412| + TP4) HIF421 0.24105 HIF421/ 0.23448 SGI421 0.05924 |SGI421|/ 0.25131 HOI (|SGI421| + TP4)

The values related to arc lengths may be obtained according to table 9 and table 10.

Fifth optical embodiment (Reference wavelength = 555 nm) ARE ARE − 2(ARE/HEP) ARE/TP ARE 1/2(HEP) value 1/2(HEP) % TP (%) 11 0.368 0.374 0.00578 101.57% 0.210 178.10% 12 0.366 0.368 0.00240 100.66% 0.210 175.11% 21 0.372 0.375 0.00267 100.72% 0.170 220.31% 22 0.372 0.371 −0.00060 99.84% 0.170 218.39% 31 0.372 0.372 −0.00023 99.94% 0.349 106.35% 32 0.372 0.404 0.03219 108.66% 0.349 115.63% 41 0.372 0.373 0.00112 100.30% 0.176 211.35% 42 0.372 0.387 0.01533 104.12% 0.176 219.40% ARS ARS − ARS/TP ARS EHD value EHD (ARS/EHD) % TP (%) 11 0.368 0.374 0.00578 101.57% 0.210 178.10% 12 0.366 0.368 0.00240 100.66% 0.210 175.11% 21 0.387 0.391 0.00383 100.99% 0.170 229.73% 22 0.458 0.460 0.00202 100.44% 0.170 270.73% 31 0.476 0.478 0.00161 100.34% 0.349 136.76% 32 0.494 0.538 0.04435 108.98% 0.349 154.02% 41 0.585 0.624 0.03890 106.65% 0.176 353.34% 42 0.798 0.866 0.06775 108.49% 0.176 490.68%

The Sixth Optical Embodiment

Please refer to FIG. 30 and FIG. 31. FIG. 30 is a schematic diagram of the optical image capturing module according to the sixth optical embodiment of the present invention. FIG. 31 is a curve diagram of spherical aberration, astigmatism, and optical distortion of the optical image capturing module sequentially displayed from left to right according to the sixth optical embodiment of the present invention. As shown in FIG. 30, the optical image capturing module includes a first lens 2411, an aperture 250, a second lens 2421, a third lens 2431, an IR-cut filter 300, an image plane 600, and image sensor elements 140 sequentially displayed from an object side surface to an image side surface.

The first lens 2411 has positive refractive power and is made of a plastic material. The object side surface 24112 thereof is a convex surface and the image side surface 24114 thereof is a concave surface, both of which are aspheric.

The second lens 2421 has negative refractive power and is made of a plastic material. The object side surface thereof 24212 is a concave surface and the image side surface thereof 24214 is a convex surface, both of which are aspheric. The image side surface 24214 thereof both has an inflection point.

The third lens 2431 has positive refractive power and is made of a plastic material. The object side surface 24312 thereof is a convex surface and the image side surface 24314 thereof is a concave surface, both of which are aspheric. The object side surface 24312 thereof has two inflection points and the image side surface 24314 thereof has an infection point.

The IR-cut filter 300 is made of glass and is disposed between the third lens 2431 and the image plane 600, which does not affect the focal length of the optical image capturing module.

Please refer to the following Table 11 and Table 12.

TABLE 11 Data of the optical image capturing module of the sixth optical embodiment f = 2.41135 mm; f/HEP = 2.22; HAF = 36 deg Surface Curvature radius Thickness (mm) Material 0 Object 1E+18 600 1 Lens 1 0.840352226 0.468 Plastic 2 2.271975602 0.148 3 Aperture 1E+18 0.277 4 Lens 2 −1.157324239 0.349 Plastic 5 −1.968404008 0.221 6 Lens 3 1.151874235 0.559 Plastic 7 1.338105159 0.123 8 IR-cut filter 1E+18 0.210 BK7 9 1E+18 0.547 10 Image plane 1E+18 0.000 Surface Refractive index Dispersion coefficient Focal length 0 1 1.535 56.27 2.232 2 3 4 1.642 22.46 −5.221 5 6 1.544 56.09 7.360 7 8 1.517 64.13 9 10 Reference wavelength (d-line) = 555 nm. Shield position: The radius of the clear aperture of the first surface is 0.640 mm

Table 12. The Aspheric Surface Parameters of the Sixth Optical Embodiment

TABLE 12 Aspheric Coefficients Surface 1 2 4 5 k= −2.019203E−01 1.528275E+01 3.743939E+00 −1.207814E+01 A4= 3.944883E−02 −1.670490E−01 −4.266331E−01 −1.696843E+00 A6= 4.774062E−01 3.857435E+00 −1.423859E+00 5.164775E+00 A8= −1.528780E+00 −7.091408E+01 4.119587E+01 −1.445541E+01 A10= 5.133947E+00 6.365801E+02 −3.456462E+02 2.876958E+01 A12= −6.250496E+00 −3.141002E+03 1.495452E+03 −2.662400E+01 A14= 1.068803E+00 7.962834E+03 −2.747802E+03 1.661634E+01 A16= 7.995491E+00 −8.268637E+03 1.443133E+03 −1.327827E+01 Surface 6 7 k= −1.276860E+01 −3.034004E+00 A4= −7.396546E−01 −5.308488E−01 A6= 4.449101E−01 4.374142E−01 A8= 2.622372E−01 −3.111192E−01 A10= −2.510946E−01 1.354257E−01 A12= −1.048030E−01 −2.652902E−02 A14= 1.462137E−01 −1.203306E−03 A16= −3.676651E−02 7.805611E−04

In the sixth optical embodiment, the aspheric surface formula is presented in the same way in the first optical embodiment. In addition, the definitions of parameters in following tables are the same as those in the first optical embodiment. Therefore, similar description shall not be illustrated again.

The values stated as follows may be deduced according to Table 11 and Table 12.

Sixth optical embodiment (Primary reference wavelength: 555 nm) |f/f1| |f/f2| |f/f3| |f1/f2| |f2/f3| TP1/TP2 1.08042 0.46186 0.32763 2.33928 1.40968 1.33921 ΣPPR ΣNPR ΣPPR/ IN12/f IN23/f TP2/TP3 |ΣNPR| 1.40805 0.46186 3.04866 0.17636 0.09155 0.62498 TP2/ (TP1 + IN12)/TP2 (TP3 + IN23)/TP2 (IN12 + TP2 + IN23) 0.35102 2.23183 2.23183 HOS InTL HOS/HOI InS/HOS |ODT| % |TDT| % 2.90175 2.02243 1.61928 0.78770 1.50000 0.71008 HVT21 HVT22 HVT31 HVT32 HVT32/HOI HVT32/ HOS 0.00000 0.00000 0.46887 0.67544 0.37692 0.23277 PhiA PhiC PhiD TH1 TH2 HOI 2.716 mm 3.116 mm 3.616 mm 0.25 mm 0.2 mm 1.792 mm PhiA/ TH1 + TH2 (TH1 + TH2)/ (TH1 + TH2)/ 2(TH1 + TH2)/ InTL/HOS PhiD HOI HOS PhiA 0.7511 0.45 mm 0.2511 0.1551 0.3314 0.6970 PLTA PSTA NLTA NSTA SLTA SSTA −0.002 mm 0.008 mm 0.006 mm −0.008 mm −0.007 mm 0.006 mm

The values stated as follows may be deduced according to Table 11 and Table 12.

Related inflection point values of sixth optical embodiment (Primary reference wavelength: 555 nm) HIF221 0.5599 HIF221/ 0.3125 SGI221 −0.1487 |SGI221|/ 0.2412 HOI (|SGI221| + TP2) HIF311 0.2405 HIF311/ 0.1342 SGI311 0.0201 |SGI311|/ 0.0413 HOI (|SGI311| + TP3) HIF312 0.8255 HIF312/ 0.4607 SGI312 −0.0234 |SGI312|/ 0.0476 HOI (|SGI312| + TP3) HIF321 0.3505 HIF321/ 0.1956 SGI321 0.0371 |SGI321|/ 0.0735 HOI (|SGI321| + TP3)

The values related to arc lengths may be obtained according to table 11 and table 12.

Sixth optical embodiment (Reference wavelength = 555 nm) ARE ARE − 2(ARE/HEP) ARE/TP ARE 1/2(HEP) value 1/2(HEP) % TP (%) 11 0.546 0.598 0.052 109.49% 0.468 127.80% 12 0.500 0.506 0.005 101.06% 0.468 108.03% 21 0.492 0.528 0.036 107.37% 0.349 151.10% 22 0.546 0.572 0.026 104.78% 0.349 163.78% 31 0.546 0.548 0.002 100.36% 0.559 98.04% 32 0.546 0.550 0.004 100.80% 0.559 98.47% ARS ARS/TP ARS EHD value ARS − EHD (ARS/EHD) % TP (%) 11 0.640 0.739 0.099 115.54% 0.468 158.03% 12 0.500 0.506 0.005 101.06% 0.468 108.03% 21 0.492 0.528 0.036 107.37% 0.349 151.10% 22 0.706 0.750 0.044 106.28% 0.349 214.72% 31 1.118 1.135 0.017 101.49% 0.559 203.04% 32 1.358 1.489 0.131 109.69% 0.559 266.34%

The optical image capturing module 10 in the present invention may be applied to one of an electronic portable device, an electronic wearable device, an electronic monitoring device, an electronic information device, an electronic communication device, a machine vision device, a vehicle electronic device, and combinations thereof.

Specifically, the optical image capturing module in the present invention may be one of an electronic portable device, an electronic wearable device, an electronic monitoring device, an electronic information device, an electronic communication device, a machine vision device, a vehicle electronic device, and combinations thereof. Moreover, required space may be minimized and visible areas of the screen may be increased by using different numbers of lens assemblies depending on requirements.

Please refer to FIG. 32 which illustrates the optical image capturing module 712 and the optical image capturing module 714 in the present invention applied to a mobile communication device 71 (Smart Phone). FIG. 33 illustrates the optical image capturing module 722 in the present invention applied to a mobile information device 72 (Notebook). FIG. 34 illustrates the optical image capturing module 732 in the present invention applied to a smart watch 73. FIG. 35 illustrates the optical image capturing module 742 in the present invention applied to a smart hat 74. FIG. 36 illustrates the optical image capturing module 752 in the present invention applied to a safety monitoring device 75 (IP Cam). FIG. 37 illustrates the optical image capturing module 762 in the present invention applied to a vehicle imaging device 76. FIG. 38 illustrates the optical image capturing module 772 in the present invention applied to a unmanned aircraft device 77. FIG. 39 illustrates the optical image capturing module 782 in the present invention applied to an extreme sport imaging device 78.

In addition, the present invention further provides a manufacturing method of an optical image capturing module, as shown in FIG. 40, which may include the following steps:

S101: disposing a circuit assembly 100 and the circuit assembly 100 including a circuit substrate 120, a plurality of image sensor elements 140, and a plurality of signal transmission elements 160;

S102: electrically connecting the plurality of signal transmission elements 160 between the plurality of circuit contacts 122 on the circuit substrate 120 and the plurality of image contacts 122 on a second surface 144 of each of the image sensor elements 140;

S103: forming a multi-lens frame 180 integrally, and forming a plurality of light channels 182 on a sensing surface 1441 of the second surface 144 corresponding to each of the image sensor elements 140;

S104: covering the multi-lens frame 180 on the circuit assembly 100 and surrounding the plurality of image sensor elements 140 and the signal transmission element 160 of the circuit assembly 100 with the multi-lens frame;

S105: disposing a lens assembly 200, which includes a plurality of lens bases 220, a plurality of auto-focus lens assembly 240, and a plurality of driving assemblies 260;

S106: making the lens base 220 with an opaque material and forming an accommodating hole 2201 on the lens base 220 which passes through two ends of the lens base 220 in such a way that the lens base 220 becomes a hollow shape:

S107: disposing the lens bases 220 on the multi-lens frame 180 to connect the accommodating hole 2201 with the light channel 182;

S108: disposing at least two lenses 2401 with refractive power in each of the auto-focus lens assemblies 240 and making each of the auto-focus lens assemblies 240 satisfy the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm; 0<PhiA/PhiD≤0.99; and 0≤2(ARE,HEP)≤2.0;

In the conditions above, f is a focal length of the auto-focus lens assembly 240. HEP is the entrance pupil diameter of the auto-focus lens assembly 240. HAF is the half maximum angle of view of the auto-focus lens assembly 240. PhiD is the maximum value of a minimum side length of an outer periphery of the lens base 220 perpendicular to an optical axis of the auto-focus lens assembly 240, PhiA is the maximum effective diameter of the auto-focus lens assembly 240 nearest to a lens 2401 surface of an image plane. ARE is the are length along an outline of the lens 2401 surface, starting from an intersection point of any lens 2401 surface of any lens 2401 and the optical axis in the auto-focus lens assembly 240, and ending at a point with a vertical height which is a distance from the optical axis to half the entrance pupil diameter.

S109: disposing each of the auto-focus lens assemblies 240 on each of the lens bases 220 and positioning each of the auto-focus lens assemblies in the accommodating hole 2201;

S110: adjusting the image planes of each of the auto-focus lens assemblies 240 of the lens assembly 200 to make the image plane of each of the auto-focus lens assemblies 240 of the lens assembly 200 position on the sensing surface 1441 of each of the image sensor elements 140, and to make the optical axis of each of the auto-focus lens assemblies 240 overlap with a central normal line of the sensing surface 1441; and

S111: electrically connecting the driving assembly 260 to the circuit substrate 120 to couple with the auto-focus lens 240 assembly so as to drive the auto-focus lens assembly 240 to move in a direction of the central normal line of the sensing surface 1441.

Specifically, by employing S101 and S111, smoothness is ensured with the feature of the multi-lens frame 180 manufactured integrally. Through the manufacturing process of AA (Active Alignment), in any step from S101 to S111, the relative positions between each of the elements may be adjusted, including the circuit substrate 120, the image sensor elements 140, the lens base 220, the plurality of auto-focus lens assemblies 240, the plurality of driving assemblies 260, and the optical image capturing module 10. This allows light to be able to pass through each of the auto-focus lens assemblies 240 in the accommodating hole 2201, pass through the light channel 182, and be emitted to the sensing surface 1441. The image planes of each of the auto-focus lens assemblies 240 may be disposed on the sensing surface 1441. An optical axis of each of the auto-focus lens assemblies 240 may overlap the central normal line of the sensing surface 1441 to ensure image quality.

Please refer to FIG. 2 to FIG. 8 and FIG. 41 to FIG. 43. The present invention further provides an optical image capturing module 10 including a circuit assembly, a lens assembly 200, and a multi-lens outer frame 190. The lens assembly 100 includes a circuit substrate 120, a plurality of image sensor elements 140, a plurality of signal transmission elements 160. The lens assembly 200 may include a plurality of lens bases 220, a plurality of auto-focus lens assemblies 240, and a plurality of driving assemblies 260.

The circuit substrate 120 may include a plurality of circuit contacts 120. Each of the image sensor elements 140 may include a first surface 142 and a second surface 144. LS is a maximum value of a minimum side length of an outer periphery of the image sensor elements 140 perpendicular to the optical axis on the surface. The first surface 142 may be connected to the circuit substrate 120. The second surface 144 may have a sensing surface 1441. The plurality of signal transmission elements 160 may be electrically connected between the plurality of circuit contacts 122 on the circuit substrate 120 and each of the plurality of image contacts 140 of each of the image sensor elements 146.

The plurality of lens bases 220 may be made of opaque material and have an accommodating hole 2201 passing through two ends of the lens bases 220 so that the lens bases 220 become hollow, and the lens bases 220 may be disposed on the circuit substrate 120. In an embodiment, the multi-lens frame 180 may be disposed on the circuit substrate 120, and then the lens base 220 may be disposed on the multi-lens frame 180 and the circuit substrate 120.

Each of the auto-focus lens assemblies 240 may have at least two lenses 2401 with refractive power, be disposed on the lens base 220, and be positioned in the accommodating hole 2201. The image planes of each of the auto-focus lens assemblies 240 may be disposed on the sensing surface 1441. An optical axis of each of the auto-focus lens assemblies 240 may overlap the central normal line of the sensing surface 1441 in such a way that light is able to pass through each of the auto-focus lens assemblies 240 in the accommodating hole 2201, pass through the light channel 182, and be emitted to the sensing surface 1441 to ensure image quality. In addition, PhiB denotes the maximum diameter of the image side surface of the lens nearest to the image plane in each of the auto-focus lens assemblies 240. PhiA, also called the optical exit pupil, denotes a maximum effective diameter of the image side surface of the lens nearest to the image plane (image space) in each of the auto-focus lens assemblies 240.

Each of the driving assemblies 260 may be electrically connected to the circuit substrate 120 and drive each of the auto-focus lens assemblies 240 to move in a direction of the central normal line of the sensing surface 1441. Moreover, in an embodiment, the driving assembly 260 may include a voice coil motor to drive each of the auto-focus lens assemblies 240 to move in a direction of the central normal line of the sensing surface 1441.

In addition, each of the lens bases 220 may respectively be fixed to the multi-lens outer frame 190 in order to form a whole body of the optical image capturing module 10. This may make the structure of the overall optical image capturing module 10 more steady and protect the circuit assembly 100 and the lens assembly 200 from impact and dust.

The auto-focus lens assembly 240 further satisfies the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm; 0<PhiA/PhiD≤0.99; and 0≤2(ARE,HEP)≤2.0;

Specifically, f is the focal length of the auto-focus lens assembly 240. HEP is the entrance pupil diameter of the auto-focus lens assembly 240. HAF is the half maximum angle of view of the auto-focus lens assembly 240. PhiD is the maximum value of a minimum side length of an outer periphery of the lens base perpendicular to the optical axis of the auto-focus lens assembly 240. PhiA is the maximum effective diameter of the auto-focus lens assembly 240 nearest to a lens surface of the image plane. ARE is the arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly 240, and ending at a point with a vertical height which is a distance from the optical axis to half the entrance pupil diameter.

Moreover, in each of the embodiments and the manufacturing method, each of the lens assemblies included in the optical image capturing module provided by the present invention is individually packaged. For example, the auto-focus lens assemblies are individually packaged so as to realize their respective functions and equip themselves with a fine imaging quality.

The above description is merely illustrative rather than restrictive. Any equivalent modification or alteration without departing from the spirit and scope of the present invention should be included in the appended claims. 

What is claimed is:
 1. An optical image capturing module, comprising: a circuit assembly, comprising: a circuit substrate, comprising a plurality of circuit contacts; a plurality of image sensor elements, each of the image sensor elements comprising a first surface and a second surface, the first surface connected to the circuit substrate, and the second surface having a sensing surface and a plurality of image contacts; a plurality of signal transmission elements, electrically connected between the plurality of circuit contacts on the circuit substrate and each of the plurality of image contacts of each of the image sensor elements; and a multi-lens frame, manufactured integrally, covered on the circuit substrate, and surrounding the image sensing elements and the signal transmission elements, and positions corresponding to the sensing surface of the plurality of image sensor elements having a plurality of light channels; and a lens assembly, comprising a plurality of lens bases, each of the lens bases made of an opaque material and having an accommodating hole passing through two ends of the lens base in such a way that the lens base becomes a hollow shape, and each of the lens bases disposed on the multi-lens frame in such a way that the accommodating hole is connected to the light channel; and a plurality of auto-focus lens assemblies, each of the auto-focus lens assemblies having at least two lenses with refractive power, disposed on the lens base and positioned in the accommodating hole, an image plane of each of the auto-focus lens assemblies positioned on the sensing surface, and an optical axis of each of the auto-focus lens assemblies overlapping a central normal line of the sensing surface in such a way that light is able to pass through each of the auto-focus lens assemblies in the accommodating hole, pass through the light channel, and be emitted to the sensing surface; and a plurality of driving assemblies electrically connected to the circuit substrate, and driving each of the auto-focus lens assemblies to move in a direction of the central normal line of the sensing surface; wherein, the auto-focus lens assembly further satisfies the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm 0<PhiA/PhiD≤0.99; and 0.9≤2(ARE/HEP)≤2.0; 01.≤InS/HOS≤1.1; and IN12/f≤60; wherein, f is a focal length of the auto-focus lens assembly; HEP is an entrance pupil diameter of the auto-focus lens assembly; HAF is a half maximum angle of view of the auto-focus lens assembly; PhiD is a maximum value of a minimum side length of an outer periphery of the lens base perpendicular to the optical axis of the auto-focus lens assembly; PhiA is a maximum effective diameter of the auto-focus lens assembly nearest to a lens surface of the image plane; ARE is an arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly, and ending at a point with a vertical height which is a distance from the optical, axis to half the entrance pupil diameter; InS is a distance from the light diaphragm (aperture) to image plane on the optical axis; HOS is a distance on the optical axis from an object side surface of a first lens to the image plane; and IN12 is a distance between the first lens and a second lens.
 2. The optical image capturing module according to claim 1, wherein the lens base comprises a lens barrel and a lens holder, the lens barrel has an upper hole which passes through two ends of the lens barrel, and the lens holder has a lower hole which passes through two ends of the lens holder, the lens barrel is disposed in the lens holder and positioned in the lower hole in such a way that the upper hole and the lower hole are connected to constitute the accommodating hole; the lens holder is fixed on the multi-lens frame in such a way that the image sensor element is positioned in the lower hole; the upper hole of the lens barrel faces the sensing surface of the image sensor element; the auto-focus lens assembly is disposed in the lens barrel and is positioned in the upper hole; the driving assembly drives the lens barrel opposite to the lens holder moving in a direction of the central normal line of the sensing surface, and PhiD is a maximum value of a minimum side length of an outer periphery of the lens holder perpendicular to the optical axis of the auto-focus lens assembly.
 3. The optical image capturing module according to claim 1, further comprising at least one data transmission line electrically connected to the circuit substrate and transmits a plurality of sensing signals generated from each of the plurality of image sensor elements.
 4. The optical image capturing module according to claim 1, wherein the plurality of image sensor elements sense a plurality of color images.
 5. The optical image capturing module according to claim 1, wherein at least one of the image sensor elements senses a plurality of black-and-white images and at least one of the image sensor elements senses a plurality of color images.
 6. The optical image capturing module according to claim 1, further comprising a plurality of IR-cut filters, and the IR-cut filter is disposed in the lens base, positioned in the accommodating hole, and located on the image sensor element.
 7. The optical image capturing module according to claim 2, further comprising a plurality of IR-cut filters, and the IR-cut filter is disposed in the lens barrel or the lens holder and positioned on the image sensor element.
 8. The optical image capturing module according to claim 1, further comprising a plurality of IR-cut filters, the lens base comprises a filter holder, the filter holder has a filter hole which passes through two ends of the filter holder, the IR-cut filter is disposed in the filter holder and positioned in the filter hole, and the filter holder corresponds to positions of the plurality of light channels and is disposed on the multi-lens frame in such a way that the IR-cut filter is positioned on the image sensor element.
 9. The optical image capturing module according to claim 8, wherein the lens base comprises a lens barrel and a lens holder, the lens barrel has an upper hole which passes through two ends of the lens barrel, the lens holder has a lower hole which passes through two ends of the lens holder, and the lens barrel is disposed in the lens holder and positioned in the lower hole; the lens holder is fixed on the filter holder, and the lower hole, the upper hole, and the filter hole are connected to constitute the accommodating hole in such a way that the image sensor element is positioned in the filter hole, and the upper hole of the lens barrel faces the sensing surface of the image sensor element; in addition, the auto-focus lens assembly is disposed in the lens barrel and positioned in the upper hole.
 10. The optical image capturing module according to claim 1, wherein materials of the multi-lens frame comprise any one of metal, conducting material, and alloy, or any combination thereof.
 11. The optical image capturing module according to claim 1, wherein materials of the multi-lens frame comprise any one of thermoplastic resin, plastic used for industries, and insulating material, or any combination thereof.
 12. The optical image capturing module according to claim 1, wherein the multi-lens frame comprises a plurality of camera lens holders, each of the camera lens holders has the light channel and a central axis, and a distance between the central axes of adjacent camera lens holders is a value between 2 mm and 200 mm.
 13. The optical image capturing module according to claim 1, wherein the driving assemblies comprises voice coil motor.
 14. The optical image capturing module according to claim 1, wherein the multi-lens frame has an outer surface, a first inner surface, and a second inner surface; the outer surface extends from a margin of the circuit substrate, and has a tilted angle α with the central normal line of the sensing surface, and a is a value between 10 to 30°; the first inner surface is an inner surface of the light channel, the first inner surface has a tilted angle β with the central normal line of the sensing surface, and β is a value between 1° to 45°; the second inner surface extends from a top surface of the circuit substrate to the light channel, and has a tilted angle γ with the central normal line of the sensing surface, and γ is a value between 1° to 3°.
 15. The optical image capturing module according to claim 1, wherein the plurality of auto-focus lens assemblies comprise a first lens assembly and a second lens assembly, and a field of view (FOV) of the second lens assembly is larger than that of the first lens assembly.
 16. The optical image capturing module according to claim 1, wherein the plurality of auto-focus lens assemblies comprise a first lens assembly and a second lens assembly, and a focal length of the first lens assembly is larger than that of the second lens assembly.
 17. The optical image capturing module according to claim 1, wherein the optical image capturing module has at least three auto-focus lens assemblies, comprising a first lens assembly, a second lens assembly, and a third lens assembly; a field of view (FOV) of the second lens assembly is larger than that of the first lens assembly, the field of view (FOV) of the second lens assembly is larger than 46°, and each of the plurality of image sensor elements correspondingly receiving lights from the first lens assembly and the second lens assembly senses a plurality of color images.
 18. The optical image capturing module according to claim 1, wherein the optical image capturing module has at least three auto-focus lens assemblies, comprising a first lens assembly, a second lens assembly, and a third lens assembly; a focal length of the first lens assembly is larger than that of the second lens assembly, and each of the plurality of image sensor elements correspondingly receiving lights from the first lens assembly and the second lens assembly senses a plurality of color images.
 19. The optical image capturing module according to claim 9, wherein the following condition is satisfied: 0<(TH1+TH2)/HOI≤0.95; wherein, TH1 is a maximum thickness of the lens holder; TH2 is a minimum thickness of the lens barrel; HOI is a maximum image height perpendicular to the optical axis on the image plane.
 20. The optical image capturing module according to claim 9, wherein the following condition is satisfied: 0 mm<TH1+TH2≤1.5 mm; wherein, TH1 is a maximum thickness of the lens holder; TH2 is a minimum thickness of the lens barrel.
 21. The optical image capturing module according to claim 9, wherein the following condition is satisfied: 0<(TH1+TH2)/HOI≤0.95; wherein, TH1 is a maximum thickness of the lens holder; TH2 is a minimum thickness of the lens barrel; HOI is a maximum image height perpendicular to the optical axis on the image plane.
 22. The optical image capturing module according to claim 1, wherein the following condition is satisfied: Wherein 0.9≤ARS/EHD≤2.0; wherein, ARS is an arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly, and ending at a maximum effective half diameter point of the lens surface; EHD is a maximum effective half diameter of any surface of any lens in the auto-focus lens assembly.
 23. The optical image capturing module according to claim 1, wherein the following conditions are satisfied: PLTA≤100 μm; PSTA≤100 μm; NLTA≤100 μm; and NSTA≤100 μm; SLTA≤100 μm; SSTA≤100 μm; wherein, HOI is first defined as a maximum image height perpendicular to the optical axis on the image plane; PLTA is a lateral aberration of the longest operation wavelength of visible light of a positive tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; PSTA is a lateral aberration of the shortest operation wavelength of visible light of a positive tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; NLTA is a lateral aberration of the longest operation wavelength of visible light of a negative tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; NSTA is a lateral aberration of the shortest operation wavelength of visible light of a negative tangential ray fan aberration of the optical image capturing module passing through a margin of an entrance pupil and incident at the image plane by 0.7 HOI; SLTA is a lateral aberration of the longest operation wavelength of visible light of a sagittal ray fan aberration of the optical image capturing module passing through the margin of the entrance pupil and incident at the image plane by 0.7 HOI; SSTA is a lateral aberration of the shortest operation wavelength of visible light of a sagittal ray fan aberration of the optical image capturing module passing through the margin of the entrance pupil and incident at the image plane by 0.7 HOI.
 24. The optical image capturing module according to claim 1, wherein the auto-focus lens assembly comprises four lenses with refractive power, which are a first lens, a second lens, a third lens, and a fourth lens sequentially displayed from an object side surface to an image side surface, and the auto-focus lens assembly satisfies the following condition: 0.1≤InTL/HOS≤0.95; wherein, HOS is a distance on the optical axis from an object side surface of the first lens to the image plane; InTL is a distance on the optical axis from an object side surface of the first lens to an image side surface of the fourth lens.
 25. The optical image capturing module according to claim 1, wherein the auto-focus lens assembly comprises five lenses with refractive power, which are a first lens, a second lens, a third lens, a four lens, and a fifth lens sequentially displayed from an object side surface to an image side surface, and the auto-focus lens assembly satisfies the following condition: 0.1≤InTL/HOS≤0.95; wherein, HOS is a distance on the optical axis from an object side surface of the first lens to the image plane; InTL is a distance on the optical axis from an object side surface of the first lens to an image side surface of the fifth lens.
 26. The optical image capturing module according to claim 1, wherein the auto-focus lens assembly comprises six lenses with refractive power, which are a first lens, a second lens, a third lens, a four lens, a fifth lens, and a sixth lens sequentially displayed from an object side surface to an image side surface, and the auto-focus lens assembly satisfies the following condition: 0.1≤InTL/HOS≤0.95; wherein, HOS is a distance on the optical axis from an object side surface of the first lens to the image plane; InTL is a distance on the optical axis from an object side surface of the first lens to an image side surface of the sixth lens.
 27. The optical image capturing module according to claim 1, wherein the auto-focus lens assembly comprises seven lenses with refractive power, which are a first lens, a second lens, a third lens, a four lens, a fifth lens, a sixth lens, and a seventh lens sequentially displayed from an object side surface to an image side surface, and the auto-focus lens assembly satisfies the following condition: 0.1≤InTL/HOS≤0.95; wherein, HOS is a distance on the optical axis from an object side surface of the first lens to the image plane; InTL is a distance on the optical axis from an object side surface of the first lens to an image side surface of the seventh lens.
 28. The optical image capturing module according to claim 1, further comprising an aperture, and the aperture satisfies a following equation: 0.2≤InS/HOS≤1.1; wherein, InS is a distance from the aperture to the image plane on the optical axis; HOS is a distance on the optical axis from a lens surface of the auto-focus lens assembly farthest from the image plane.
 29. The optical image capturing module according to claim 1, applied to one of an electronic portable device, an electronic wearable device, an electronic monitoring device, an electronic information device, an electronic communication device, a machine vision device, a vehicle electronic device, and combinations thereof.
 30. A manufacturing method of an optical image capturing module, comprising: disposing a circuit assembly comprising a circuit substrate, a plurality of image sensor elements and a plurality of signal transmission elements; electrically connecting the plurality of signal transmission elements between the plurality of circuit contacts on the circuit substrate and the plurality of image contacts on a second surface of each of the image sensor elements; forming a multi-lens frame on the circuit assembly integrally and forming a plurality of light channels on a sensing surface of the second surface corresponding to each of the image sensor elements; covering the multi-lens frame on a circuit assembly and surrounding the plurality of image sensing elements and the signal transmission elements of the circuit assembly with the multi-lens frame; disposing a lens assembly, which comprises a lens base and a plurality of auto-focus lens assemblies and a plurality of driving assemblies; making the lens base with an opaque material and forming an accommodating hole on each of the lens bases which passes through two ends of the lens base in such a way that the lens base becomes a hollow shape; disposing the lens base on the multi-lens frame to connect the accommodating hole with the light channel; disposing at least two lenses with refractive power in each of the auto-focus lens assemblies and making each of the auto-focus lens assemblies satisfy the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm 0<PhiA/PhiD≤0.99; and 0.9≤2(ARE/HEP)≤2.0; 01.≤InS/HOS≤1.1; and IN12/f≤60; in the condition above, f is a focal length of the auto-focus lens assembly; HEP is an entrance pupil diameter of the auto-focus lens assembly; HAF is a half maximum angle of view of the auto-focus lens assembly; PhiD is a maximum value of a minimum side length of an outer periphery of the lens base perpendicular to the optical axis of the auto-focus lens assembly; PhiA is a maximum effective diameter of the auto-focus lens assembly nearest to a lens surface of the image plane; ARE is an arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly, and ending at a point with a vertical height which is a distance from the optical, axis to half the entrance pupil diameter; InS is a distance from the light diaphragm (aperture) to image plane on the optical axis; HOS is a distance on the optical axis from an object side surface of a first lens to the image plane; and IN12 is a distance between the first lens and a second lens; disposing each of the auto-focus lens assemblies on the lens base and positioning the auto-focus lens assembly in the accommodating hole; adjusting the image planes of each of the auto-focus lens assemblies of the lens assembly to make the image plane of each of the auto-focus lens assemblies of the lens assembly respectively position on the sensing surface of each of the image sensor elements, and to make the optical axis of each of the auto-focus lens assemblies overlap with a central normal line of the sensing surface; electrically connecting each of the driving assemblies to the circuit substrate, and coupling each of the driving assemblies with each of the auto-focus lens assemblies to drive each of the auto-focus lens assemblies to move in a direction of the central normal line of the sensing surface.
 31. An optical image capturing module, comprising: a circuit assembly, comprising: a circuit substrate, comprising a plurality of circuit contacts; a plurality of image sensor elements, each of the image sensor elements comprising a first surface and a second surface, the first surface connected to the circuit substrate, and the second surface having a sensing surface and a plurality of image contacts; a plurality of signal transmission elements, electrically connected between the plurality of circuit contacts on the circuit substrate and each of the plurality of image contacts of each of the image sensor elements; and a lens assembly, comprising: a plurality of lens bases, each of the lens bases made of an opaque material and having an accommodating hole passing through two ends of the lens base in such a way that the lens base become a hollow shape, and each of the lens bases disposed on the circuit substrate; and a plurality of auto-focus lens assemblies, each of the auto-focus lens assemblies having at least two lenses with refractive power, disposed on the lens base and positioned in the accommodating hole, an image plane of each of the auto-focus lens assemblies positioned on the sensing surface, and an optical axis of each of the auto-focus lens assemblies overlapping a central normal line of the sensing surface in such a way that light is able to pass through each of the auto-focus lens assemblies in the accommodating hole and be emitted to the sensing surface; a plurality of driving assemblies, electrically connected to the circuit substrate and driving each of the auto-focus lens assemblies to move in a direction of the central normal line of the sensing surface; and a multi-lens outer frame, wherein each of the lens bases is respectively fixed to the multi-lens outer frame in order to form a whole body; wherein, the auto-focus lens assembly further satisfies the following conditions: 1.0≤f/HEP≤10.0; 0 deg<HAF≤150 deg; 0 mm<PhiD≤18 mm 0<PhiA/PhiD≤0.99; 0.9≤2(ARE/HEP)≤2.0; 01.≤InS/HOS≤1.1; and IN12/f≤60; wherein, f is a focal length of the auto-focus lens assembly; HEP is an entrance pupil diameter of the auto-focus lens assembly; HAF is a half maximum angle of view of the auto-focus lens assembly; PhiD is a maximum value of a minimum side length of an outer periphery of the lens base perpendicular to the optical axis of the auto-focus lens assembly; PhiA is a maximum effective diameter of the auto-focus lens assembly nearest to a lens surface of the image plane; ARE is an arc length along an outline of the lens surface, starting from an intersection point of any lens surface of any lens and the optical axis in the auto-focus lens assembly, and ending at a point with a vertical height which is a distance from the optical, axis to half the entrance pupil diameter; InS is a distance from the light diaphragm (aperture) to image plane on the optical axis; HOS is a distance on the optical axis from an object side surface of a first lens to the image plane; and IN12 is a distance between the first lens and a second lens. 